FEM Simulations of Induction Hardening Process831823/FULLTEXT01.pdfInduction heating is the process...
Transcript of FEM Simulations of Induction Hardening Process831823/FULLTEXT01.pdfInduction heating is the process...
Masters Degree Thesis
ISRN BTH-AMT-EX--2013D16--SE
Supervisors Edin Omerspahic and John Lorentzon SKF Ansel Berghuvud BTH
Department of Mechanical Engineering
Blekinge Institute of Technology
Karlskrona Sweden
2013
Heng Liu
FEM Simulations of Induction Hardening Process
FEM Simulations of Induction Hardening Process
Heng Liu
Department of Mechanical Engineering
Blekinge Institute of Technology
Karlskrona Sweden
2013
Thesis submitted for completion of Master of Science degree in Mechanical Engineering with emphasis on Structural Mechanics at the Department of Mechanical Engineering Blekinge Institute of Technology Karlskrona Sweden
Abstract
Induction heating is the process of heating an electrically conducting object by electromagnetic induction where eddy currents are generated within the metal and resistance leads to Joule heating of the metal Heating is followed by immediate quenching The quenched metal undergoes a martensitic transformation increasing the hardness of the part The process is widely used in industrial operations In this thesis the Finite Element Method (FEM) simulations of the process have been studied In practice this means that a coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon have been modeled and studied in LS-DYNA The simulation results have been compared to experimental results from literature The comparison and the softwarersquos simulation performance have been used to evaluate the maturity of LS-DYNA to model the real process
Keywords
Induction Hardening Induction Heating Quenching Modeling Simulations Phase Transformations FEM LS-DYNA
1
Acknowledgements
The research work was carried out at SKF AB Manufacturing Development Center during the spring and summer 2013 The thesis is the concluding part of an engineering degree from Department of Mechanical Engineering Blekinge Institute of Technology (BTH) Karlskrona Sweden
First of all I would like to express my sincere gratitude to my supervisors at SKF Edin Omerspahic and John Lorentzon Without their support and enthusiasm the thesis will never come out Their guidance insight conversations timely advices and comments have been a source of strength to me
Many thanks also to Marcus Lilja and Mikael Schill at DYNAMORE and Vinayak Deshmukh and Johan Facht at SKF who always helped me when I was in trouble during the research work
I would also like to thank Ansel Berghuvud my Supervisor at Blekinge Institute of Technology who supported me a lot during this thesis work
Finally I would like to thank all friends and staff at SKF for their valuable input to the thesis and their help
Goumlteborg September 2013
Heng Liu
2
Contents
Notation 3 1 Introduction 6
11 Background 6 12 Aim 9
2 Induction and the corresponding numerical background 12 21 Induction process - Maxwell equations 12
211 Skin effect and skin depth 14 212 Proximity effect 15
22 Numerical basis of the induction process 15 221 FEM model for electromagnetic field 17 222 FEM model for temperature field 19 223 FEM model for mechanical field 21 224 Numerical procedure 23
23 Microstructures in numerical model 26 24 Numerical determination of hardness 29
3 Simulation (FEM) model 31 31 Initial and boundary conditions 31 32 Meshing 33 33 Material properties 34
331 Thermal and electromagnetic properties of the bar 34 332 Mechanical and metallurgical properties of the bar 37 333 Material properties of the inductor 38
34 Limitations 38 4 Analysis and discussion of the simulation results 40
41 Magnetic results 41 42 Thermal results 44 43 Metallurgical results 45
5 Evaluation of the results 50 6 Conclusions 54 Reference 55 Appendix A Miscellaneous results 57
Explicit mechanical solver 57 Implicit mechanical solver with curve switching between heating and
cooling 58 Implicit mechanical solver with 2 successive processes ndash heating and
cooling enabled by INTERFACE_SPRINGBACK_LSDYNA 60
3
Notation
A
Vector Potential [Tm]
a u Acceleration [ms2]
B
Magnetic flux density [T]
b Material coefficient [-]
C Specific Heat [Jkg K]
cC Capacitance [F]
pC Chemical composition []
c Empirical grain growth parameter [-]
dc Damping coefficient [N sm]
E Youngrsquos Modulus [Pa]
E
Electric field [Vm]
LorentzF Lorentz force [N]
f Frequency [kHz]
Df Damping force [N]
lf Inertial force [N]
Sf Elastic force [N]
G Energy release rate [Jm2]
gG Grain number [-]
H
Magnetic field intensity [Am]
Hv Hardness [-]
h Convection coefficient [W(m2K)]
I Current [A]
j
Current density [Am2]
sj
Source current density [Am2]
k Thermal conductivity [W(m K)]
4
sk Linear stiffness [Nm]
L Inductance [H]
m Mass [kg]
Ms temperature of the initial martensitic
transformation [K]
n Normal direction of the boundary [-]
p Phase proportion [-]
eqp Phase proportion calculated at thermodynamic equilibrium
[-]
Q Internal heat generation rate per unit volume [-]
kQ Activation energy [J]
q Charge [C]
szq
Heat flux vector [-]
R Resistance [Ω]
bR Radius [m]
uR Universal gas constant [J(mol K)]
r Position [m]
T Temperature [K]
wT Surface temperature of the solid [K]
T Fluid temperature [K]
t Time [sec]
u Displacement [m]
u v Velocity [ms]
V Voltage amplitude [V]
Vr Cooling rate at 700 [Ks]
kX Actual phase [-]
kx True amount of phase [-]
Material dependent constant [-]
Stress [Pa]
B Stefan Boltzmann constant [W(m2K4)]
5
C Electric conductivity [1(Ωm)]
Strain []
0 Permittivity of free space [Fm]
e Surface emissivity [-]
Scalar Potential [V]
Skin depth [m]
Magnetic Permeability [Hm]
0 Permeability of free space [Hm]
r Relative permeability [-]
Density [kgm3]
c Total Charge density [Cm3]
e Electrical resistivity [Ωm]
Shear stress [Pa]
R Delay time of the transformation [sec]
Poissons ratio [-]
Volume [m3]
Boundary surface of volume [m2]
Pulsation [rads]
6
1 Introduction
11 Background
The induction hardening is one of the methods for heat treatment of steel workpieces The induction hardening can be used for both through-hardening and to selectively harden areas of a part or assembly When the method is used to harden only the surface of the parts it has been applied to various machine parts such as automobile components and toothed gears [1]
The classic method of hardening contains first heating to an austenitic state (austenite has a Face Centre Cubic ndash FCC atomic structure) and then cooling rapidly Let us assume the initial phase being ferritic-pearlitic Ferrite has a Body Centre Cubic structure (BCC) which can hold very little carbon typically 00001 at room temperature It can exist as either alpha or delta ferrite Pearlite is a mixture of alternate strips of ferrite and cementite in a single grain The name for this structure is derived from pearl appearance seen under a microscope A fully pearlitic structure occurs at 08 Carbon
During heating see Figure 12 two processes occur Firstly the cementite starts to dissolve and the cementite particles to shrink When the temperature rises above a critical value the ferrite starts to transform to austenite Austenite formation and cementite dissolution occur faster the higher the temperature The structure is fully austenitic above the A3 (Ac3) or Accm line (the upper line in the Iron Carbon Diagram) Figure 11
7
Figure 11 Iron Carbon Diagram
Figure 12 Induction heating of a part
During cooling from the austenitic state several different phase transformations may take place depending on how fast the cooling process is When steel is cooled sufficiently rapidly other structures do not have sufficient time to form and the austenite can be retained at low temperatures since the diffusion-dependent transformations proceed slowly When the temperature is sufficiently low the tendency of austenite to be transformed becomes so strong that the transformation takes place without diffusion Such a transformation is called diffusionless and can in principle occur with two different mechanisms namely massive and martensitic transformation [2]
Figure 13 Quenching (cooling) of a part
8
In a martensitic transformation FCC structure of austenite rapidly changes to BCC leaving insufficient time for the carbon to form pearlite This results in a distorted structure that has the appearance of fine needles Only the parts of a section that cool fast enough will form martensite in a thick section it will only form to a certain depth and if the shape is complex it may only form in small pockets The hardness of martensite is solely dependant on carbon content it is normally very high unless the carbon content is exceptionally low The martensitic transformation is of great practical significance since it is the martensite which gives steel its high degree of hardness and strength
In the induction hardening of our interest the surface of the workpiece is heated up over the austenitization temperature by the induction heating Figure 12 and transformed from the ferritic and pearlitic structure Figure 14 A to the austenite structure Figure 14 B The heating process is then followed by immediate quenching process Figure 13 and the surface of the workpiece is transformed from the austenitic to the martensitic phase Figure 14 C and thereby hardened The heating condition for the induction hardening can be determined experimentally or empirically for the workpiece of any shape [1]
Figure 14 Specimen microstructures of normalized steel A) Ferritic-Pearlitic B) Austenitic and C) Martensitic
9
Induction heating is the process of heating an electrically conducting object by electromagnetic induction where eddy currents are generated within the metal and resistance leads to Joule heating of the metal [6] This process is widely used in industrial operations due to its high efficiency precise control and more environmentally friendly properties [3] The induction heating has some characteristics compared to the traditional heating methods (such as furnace heating)
It has a precise depth of heating and the heating zone which is easier to control
It is easy to implement high power density fast heating high efficiency and low energy consumption
It is easy to control the high heating temperature
The conduction and infiltration of the heating temperature will be from the surface to the interior
There are no penetrating impurities since non-contact heating method is used
The burned part on the workpiece is smaller
The process is somewhat eco-friendly
It is easy to accomplish the automation of heating process
The quenching part of an induction hardening process is also an important part Cooling rates must be rapid in order to avoid softer undesirable structures such as pearlite and bainite Due to its importance the cooling portion of the induction hardening process deserves careful consideration particularly when specifying new induction equipment and processes Process parameters must be precisely controlled to assure consistent heat treatment results Excessive variation in these parameters will cause undesirable or inconsistent process results including problems with case depth hardness pattern and distortion [4] Water quench has been used for the problem in this thesis
12 Aim
Let us go to the main objective of this work Although the induction hardening process has many advantages the design of it which is usually based on experiments can be tiresome time-consuming and expensive
10
Luckily the fast development of the computer technology makes it possible to model the induction heat treatment process with numerical tools particularly with Finite Element Method (FEM) Nowadays a lot of engineers pay attention to this area
There are many FEM modeling works regarding either the heating or quenching heat treatment in the literature However numerical models of the integrated heat treatment ie both the induction heating and quenching are still gaining ground [5] Induction hardening is a complex physical process which has contributions from electrical magnetic thermal mechanical and metallurgical processes It is obvious that the complexity of the phenomena ndash including phase transformation and heat exchange makes the FEM analysis heavy and difficult
Different FEM softwares have been used for numerical studies of the induction hardening process In this study LS-DYNA has been used for simulations The electromagnetic field the eddy current and the temperature field have been calculated with the FEM and Boundary Element Method (BEM) In fact FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air thus no air mesh is needed The main study included
The mathematical description and the modeling of the induction heat treatment process
Solving the induction-hardening-modeling key technical issues
Simulating the induction hardening process with the existing commercial software LS-DYNA
Comparing the results of the simulation with the literature values and evaluating the softwarersquos capability
In short the aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The simulation results have been compared to literature results for evaluation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Here follows the model selected from a literature source [5] the induction heating and cooling of cylindrical workpiece The experimental setup is made of three parts the coil the bar and the cooling tool Figure 15
11
Figure 15 The experimental set-up
12
2 Induction and the corresponding numerical background
21 Induction process - Maxwell equations
The basic model is shown in Figure 21
Figure 21 Induction heating principle
The partial differential equations are used to solve the electromagnetic field distribution
In order to define the equations solved by the electromagnetic solver in LS-DYNA we start with the Maxwell equations [7]
t
BE
(21)
t
EjH
0 (22)
0 B
(23)
13
0
E
(24)
sjEj
(25)
HB
0 (26)
where E
is electric field B
is magnetic flux density t is time H
is
magnetic field intensity j
is current density 0 is permittivity of free
space is total charge density is electric conductivity sj
is source
current density and 0 is permeability of free space
The eddy current approximation used here implies a divergence-free current
density and no charge accumulation thus resulting in 00
t
E
and 0
Equations (22) and (24) in the eddy current approximation give
jH
(27)
0 E
(28)
0 j
(29)
The divergence condition given by equation (23) allows writing B
as
AB
(210)
where A
is the magnetic vector potential [8] Equation (21) then implies that the electric field is given by
t
AE
(211)
14
where is the electric scalar potential
Equation (210) leaves a mathematical degree of freedom to A
(if A
is
transformed to a given
A then Equation (210) remains valid) Therefore the introduction of a gauge ie a particular choice of the scalar and vector potentials is needed Gauge choosing denotes a mathematical procedure for coping with redundant degrees of freedom in field variables The gauge chosen here is the generalized Coulomb gauge
0 A
(212)
Equations (25) (29) (211) and (212) give
0
(213)
Equations (25) (27) (211) and (210) give
sjAt
A
1
(214)
Equation (213) and Equation (214) are the two equations constituting the system that will be solved where A
and are the two unknowns of the
problem [7]
211 Skin effect and skin depth
Skin effect is the tendency of an alternating electric current (AC) to become distributed within a conductor such that the current density is largest near the surface of the conductor and decreases with greater depths in the conductor [9]
Skin effect is associated with the current flowing mainly at the skin of the conductor at an average depth called the skin depth The skin depth is
15
defined as the depth at which the electromagnetic field in a conducting material has decreased to 037 of its value just outside the material which describes the electric and magnetic fields The formula for the skin depth is given by
ff rr
503
)2(
22
0
(215)
where is the skin depth f is the frequency is the average electrical
resistivity and r is the average relative permeability
212 Proximity effect
A changing magnetic field will influence the distribution of an electric current flowing within an electrical conductor by electromagnetic induction When an alternating current flows through an isolated conductor it creates an associated alternating magnetic field around it The alternating magnetic field induces eddy currents in adjacent conductors altering the overall distribution of current flowing through them ndash the distribution of current within the conductor will be constrained to smaller regions Subsequently the resistance is increased in those regions The resulting current crowding is termed the proximity effect Usually the current is concentrated in the areas of the conductor furthest away from nearby conductors carrying current in the same direction [10]
Thus since in our case the inductor is a coil the maximum current density will be at the inner side of the coil [3] So the inner side of the coil will be used to heat the workpiece which will get faster temperature increase and will be more efficient
22 Numerical basis of the induction process
All the physical phenomena encountered in engineering mechanics are modeled by differential equations Usually it is difficult to obtain accurate analytical solution of the differential equation However the numerical solution could be calculated but only when boundary conditions and initial
16
conditions under specific situations were given The following numerical methods are used to model the induction process in LS-DYNA
Finite Element Method
The FEM is today a powerful (often the most powerful) tool for numerical solution of any differential equation whether this arises from structural mechanics fluid mechanics thermodynamics biology ecology or any other field of science [11]
The finite element method is a numerical approach by which general differential equations can be solved in an approximate manner [12] A domain of interest is represented as an assembly of finite elements The FEM is useful for problems with complicated geometries loadings and material properties where analytical solutions cannot be obtained [13]
The main steps in the general FE formulation and solution of a physical problem are [11]
o Establish the strong form of the governing differential equation
o Transform this differential equation into the weak form
o Choose trial functions for the unknown function that is choose element type(s) and mesh the solution domain
o Choose weight functions and establish the system of algebraic equations for each element (element equations)
o Assemble these element systems into the global system of algebraic equations
o Introduce boundary conditions into the global system of algebraic equations
o Solve the system of algebraic equations and present the results or use them for further calculations
Boundary Element Method
The boundary element method (BEM) is a numerical computational method of solving linear partial differential equations which have been formulated as integral equations BEM attempts to use the given boundary conditions to fit only boundary values into the integral equation Once this is done the integral equation can then be used again to calculate numerically solution at any desired point in the interior of the solution domain The boundary
17
element method is often more efficient than other methods including FEM in terms of computational resources for problems where there is a small surfacevolume ratio Conceptually it works by constructing a mesh over the modeled surface However for many problems boundary element methods are significantly less suitable and efficient than volume-discretization methods [14]
In numerical computations of the problem in this thesis with LS-DYNA FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air
221 FEM model for electromagnetic field
In LS-DYNA equation (213) is projected on the 0W forms (0-forms are continuous scalar basis functions that have a well defined gradient the gradient of a 0-form being a 1- form) and equation (214) is projected on
the 1W
forms (1-forms are vector basis functions with continuous tangential components but discontinuous normal components) They have a well defined curl the curl of a 1-form being a 2-form) giving after integrating by part the following weak formulations [15]
00 dW
(216)
dWAndW
dWAdWt
A
11
11
)(
1
(217)
where d an element of volume and the surface of with n
outer normal to
The and A
decompositions on respectfully 0W and 1W
give
0iiw (218)
1iiwaA
(219)
18
When replacing and A
in equation (216) and (217) by (218) and (219) one gets
0)(0 S (220)
SaDaSt
aM
)()
1()( 0111
(221)
where
the stiffness matrix of the 0-forms is given by
dWWjiS ji000 ))((
(222)
the mass matrix of the 1-forms is given by
dWWjiM ji111 ))((
(223)
the stiffness matrix of the 1-forms is given by
dWWjiS ji )()(1
))(1
( 111
(224)
the derivative matrix of the 0-1-forms is given by
dWWjiD ji )())(( 1001
(225)
the outside stiffness matrix is given by
19
dWWnjiS ji11)(
1))(
1(
(226)
where is the magnetic permeability n
is the normal vector is the volume and is the boundary surface of volume
Equation (220) and (221) form the FEM system with and a being the unknowns From this system only the outside stiffness matrix cannot be directly computed The calculation of this matrix will be made possible through the definition of the BEM system [7] The BEM system is used for the air and will not be shown in this report More information about it could be found in [7]
222 FEM model for temperature field
The steady state or transient temperature field on three dimensional geometries can also be solved by LS-DYNA Material properties may be temperature dependent and either isotopic or orthotropic A variety of time and temperature dependent boundary conditions can be specified including temperature flux convection and radiation The implementation of heat conduction into LS-DYNA is based on the work of Shapiro [16]
The differential equations of conduction of heat in a three-dimensional continuum is given by
Qkt
cijij
(227)
where )( txi is temperature )( ix is density )( ixcc is
the specific heat )( iijij xkk is thermal conductivity )( ixQQ is
internal heat generation rate per unit volume
The boundary conditions are
s on 1 (228)
20
ijij nk on 2 (229)
Initial conditions at 0t are given by
)(0 ix at 0tt (230)
where )(txx ii are coordinates as a function of time is prescribed
temperature on 1 and in is normal vector to 2
Equations (227-230) represent the strong form of a boundary value problem to be solved for the temperature field within the solid continuum [16]
The finite element method provides the following equations for the numerical solution of equations (227-230)
nnnnnnn HFHt
C
1 (231)
e
jie
eij
e
dcNNCC (232)
ejiji
T
e
eij
ee
dNNdNKNHH (233)
eigi
e
ei
ee
dNdqNFF (234)
where and are the parameters that are different when using different methods like Crank-Nicolson Galerkin and so on The parameter is taken to be in the interval [01] C H and F are the element stiffness load and boundary matrices respectively N is the element shape functions gq is the heat flow K is the thermal conductivity tensor
21
The boundary conditions for temperature flux convection and radiation are
)(
)(
)(
42
4112 TTF
n
T
TThn
T
qn
Tk
tzyxfT
w
sz
(235)
where T is the temperature k is the thermal conductivity n is the normal direction of the boundary szq
is the heat flux vector h is the convective
heat transfer coefficient wT is the surface temperature of the solid T is
the fluid temperature is the emissivity is the Stefan Boltzmann constant
223 FEM model for mechanical field
The equations that govern analyses of the behavior of a solid continuum are those of momentum conservation ie the equations of motion For an analysis of small deformation of a solid continuum these are (in tensor form) [17]
iijij ub (236)
where ij is the Cauchy stress tensor ib the body force vector per unit
volume the density and iu the displacement vector
To establish a weak form from the strong one we multiply (236) by an arbitrary velocity ie the test function iv and integrate over the region
By introducing two boundary conditions ii uu on u and ijijn on
where 0v on u the above differential equation in the weak form
[17] is given as
22
dvdbvduvdv iiiiiiijji (237)
To perform the FE discretization of the weak form (237) means to divide the continuum volume into sub-elements where the displacement field in every element is approximated by shape functions )(xNI and nodal
displacements )(tuiI that is summation of their products [17]
)()()( xNtutxu IiIi (238)
By approximating the test functions with the same shape functions (Galerkin method) we obtain
0)(
)()(
)(
)(
)(
)(
int)(
int
int
ee
e
e
dNbdNff
NdNMM
x
NBdBff
fuMfv
TTexte
ext
Te
j
IjI
Te
extT
(239)
which must hold for an arbitrary v and which puts the FE equation in order
intffuM ext (240)
For a linear material C the FE equation that emerges is
23
)(
)(e
dCBBKKfKuuM TTeext (241)
224 Numerical procedure
For the induction hardening process three different analyses have been combined in one numerical procedure mechanical thermal-metallurgical and electromagnetic (EM) computations They are solved fully transiently Boundary conditions and material properties beside one unique geometric model were required by each of them
What is necessary to mention is that some characteristics of the material are interdependent The electric conductivity for instance depends on the temperature In addition all thermal properties depend on the temperature [18] The variation of the properties with the temperature makes the system to be non-linear
There is a high coupling grade between thermal and EM equations because the electrical and magnetic properties laws depend on temperature When the initial temperature is known the eddy current value is calculated and then used to compute the heat generated by the Joule effect [5] At each time step the convergence is checked Until a steady state between the heat and the temperature field is reached the temperature value will be recalculated for each magnetic sub-step
EM solver can be coupled with the thermal and mechanical solvers in order to take full advantage of their capabilities [7] Both the thermal and the EM solver run with implicit time integration For mechanical solver there are two time integration methods of explicit and implicit type
Explicit and implicit methods are numerical schemes for obtaining numerical solutions of time-dependent ordinary and partial differential equations as is required in computer simulations of physical processes Explicit methods calculate the state of a system at a later time from the state of the system at the current time while implicit methods find a solution by solving an equation involving both the current state of the system and the later one [19] Here follows the difference between explicit and implicit methods
Implicit method
o More accurate
24
o It has large time step increment
o Convergence of each load step can be controlled to avoid error accumulation
o Iteration may not converge
Explicit method
o Less accurate
o It has small time step
o There is error accumulation and the error is difficult to estimate
o Iteration converges
However the implicit type has been governing the mechanical solver for the induction process in this thesis
Now let us go back to the couplings For the electromagnetic and structure interaction both the mechanical and the EM solver have distinct time steps By linear interpolation the EM fields are evaluated at the mechanical time step The two solvers will interact at each electromagnetic time step The EM solver will communicate the Lorentz force to the mechanical solver [7] resulting in an extra force in the mechanic equation
Lorentzext FfDt
Du (242)
where is total charge density is electrical conductivity extf is the
external force while LorentzF is the Lorentz force In turn the displacements
and deformations of the conductors are returned by the mechanical solver
When it comes to the thermal coupling at each electromagnetic time step the EM solver will communicate the extra Joule heating power term and the thermal solver will communicate the temperature
Figure 22 shows the interactions between the different solvers in LS-DYNA
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
FEM Simulations of Induction Hardening Process
Heng Liu
Department of Mechanical Engineering
Blekinge Institute of Technology
Karlskrona Sweden
2013
Thesis submitted for completion of Master of Science degree in Mechanical Engineering with emphasis on Structural Mechanics at the Department of Mechanical Engineering Blekinge Institute of Technology Karlskrona Sweden
Abstract
Induction heating is the process of heating an electrically conducting object by electromagnetic induction where eddy currents are generated within the metal and resistance leads to Joule heating of the metal Heating is followed by immediate quenching The quenched metal undergoes a martensitic transformation increasing the hardness of the part The process is widely used in industrial operations In this thesis the Finite Element Method (FEM) simulations of the process have been studied In practice this means that a coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon have been modeled and studied in LS-DYNA The simulation results have been compared to experimental results from literature The comparison and the softwarersquos simulation performance have been used to evaluate the maturity of LS-DYNA to model the real process
Keywords
Induction Hardening Induction Heating Quenching Modeling Simulations Phase Transformations FEM LS-DYNA
1
Acknowledgements
The research work was carried out at SKF AB Manufacturing Development Center during the spring and summer 2013 The thesis is the concluding part of an engineering degree from Department of Mechanical Engineering Blekinge Institute of Technology (BTH) Karlskrona Sweden
First of all I would like to express my sincere gratitude to my supervisors at SKF Edin Omerspahic and John Lorentzon Without their support and enthusiasm the thesis will never come out Their guidance insight conversations timely advices and comments have been a source of strength to me
Many thanks also to Marcus Lilja and Mikael Schill at DYNAMORE and Vinayak Deshmukh and Johan Facht at SKF who always helped me when I was in trouble during the research work
I would also like to thank Ansel Berghuvud my Supervisor at Blekinge Institute of Technology who supported me a lot during this thesis work
Finally I would like to thank all friends and staff at SKF for their valuable input to the thesis and their help
Goumlteborg September 2013
Heng Liu
2
Contents
Notation 3 1 Introduction 6
11 Background 6 12 Aim 9
2 Induction and the corresponding numerical background 12 21 Induction process - Maxwell equations 12
211 Skin effect and skin depth 14 212 Proximity effect 15
22 Numerical basis of the induction process 15 221 FEM model for electromagnetic field 17 222 FEM model for temperature field 19 223 FEM model for mechanical field 21 224 Numerical procedure 23
23 Microstructures in numerical model 26 24 Numerical determination of hardness 29
3 Simulation (FEM) model 31 31 Initial and boundary conditions 31 32 Meshing 33 33 Material properties 34
331 Thermal and electromagnetic properties of the bar 34 332 Mechanical and metallurgical properties of the bar 37 333 Material properties of the inductor 38
34 Limitations 38 4 Analysis and discussion of the simulation results 40
41 Magnetic results 41 42 Thermal results 44 43 Metallurgical results 45
5 Evaluation of the results 50 6 Conclusions 54 Reference 55 Appendix A Miscellaneous results 57
Explicit mechanical solver 57 Implicit mechanical solver with curve switching between heating and
cooling 58 Implicit mechanical solver with 2 successive processes ndash heating and
cooling enabled by INTERFACE_SPRINGBACK_LSDYNA 60
3
Notation
A
Vector Potential [Tm]
a u Acceleration [ms2]
B
Magnetic flux density [T]
b Material coefficient [-]
C Specific Heat [Jkg K]
cC Capacitance [F]
pC Chemical composition []
c Empirical grain growth parameter [-]
dc Damping coefficient [N sm]
E Youngrsquos Modulus [Pa]
E
Electric field [Vm]
LorentzF Lorentz force [N]
f Frequency [kHz]
Df Damping force [N]
lf Inertial force [N]
Sf Elastic force [N]
G Energy release rate [Jm2]
gG Grain number [-]
H
Magnetic field intensity [Am]
Hv Hardness [-]
h Convection coefficient [W(m2K)]
I Current [A]
j
Current density [Am2]
sj
Source current density [Am2]
k Thermal conductivity [W(m K)]
4
sk Linear stiffness [Nm]
L Inductance [H]
m Mass [kg]
Ms temperature of the initial martensitic
transformation [K]
n Normal direction of the boundary [-]
p Phase proportion [-]
eqp Phase proportion calculated at thermodynamic equilibrium
[-]
Q Internal heat generation rate per unit volume [-]
kQ Activation energy [J]
q Charge [C]
szq
Heat flux vector [-]
R Resistance [Ω]
bR Radius [m]
uR Universal gas constant [J(mol K)]
r Position [m]
T Temperature [K]
wT Surface temperature of the solid [K]
T Fluid temperature [K]
t Time [sec]
u Displacement [m]
u v Velocity [ms]
V Voltage amplitude [V]
Vr Cooling rate at 700 [Ks]
kX Actual phase [-]
kx True amount of phase [-]
Material dependent constant [-]
Stress [Pa]
B Stefan Boltzmann constant [W(m2K4)]
5
C Electric conductivity [1(Ωm)]
Strain []
0 Permittivity of free space [Fm]
e Surface emissivity [-]
Scalar Potential [V]
Skin depth [m]
Magnetic Permeability [Hm]
0 Permeability of free space [Hm]
r Relative permeability [-]
Density [kgm3]
c Total Charge density [Cm3]
e Electrical resistivity [Ωm]
Shear stress [Pa]
R Delay time of the transformation [sec]
Poissons ratio [-]
Volume [m3]
Boundary surface of volume [m2]
Pulsation [rads]
6
1 Introduction
11 Background
The induction hardening is one of the methods for heat treatment of steel workpieces The induction hardening can be used for both through-hardening and to selectively harden areas of a part or assembly When the method is used to harden only the surface of the parts it has been applied to various machine parts such as automobile components and toothed gears [1]
The classic method of hardening contains first heating to an austenitic state (austenite has a Face Centre Cubic ndash FCC atomic structure) and then cooling rapidly Let us assume the initial phase being ferritic-pearlitic Ferrite has a Body Centre Cubic structure (BCC) which can hold very little carbon typically 00001 at room temperature It can exist as either alpha or delta ferrite Pearlite is a mixture of alternate strips of ferrite and cementite in a single grain The name for this structure is derived from pearl appearance seen under a microscope A fully pearlitic structure occurs at 08 Carbon
During heating see Figure 12 two processes occur Firstly the cementite starts to dissolve and the cementite particles to shrink When the temperature rises above a critical value the ferrite starts to transform to austenite Austenite formation and cementite dissolution occur faster the higher the temperature The structure is fully austenitic above the A3 (Ac3) or Accm line (the upper line in the Iron Carbon Diagram) Figure 11
7
Figure 11 Iron Carbon Diagram
Figure 12 Induction heating of a part
During cooling from the austenitic state several different phase transformations may take place depending on how fast the cooling process is When steel is cooled sufficiently rapidly other structures do not have sufficient time to form and the austenite can be retained at low temperatures since the diffusion-dependent transformations proceed slowly When the temperature is sufficiently low the tendency of austenite to be transformed becomes so strong that the transformation takes place without diffusion Such a transformation is called diffusionless and can in principle occur with two different mechanisms namely massive and martensitic transformation [2]
Figure 13 Quenching (cooling) of a part
8
In a martensitic transformation FCC structure of austenite rapidly changes to BCC leaving insufficient time for the carbon to form pearlite This results in a distorted structure that has the appearance of fine needles Only the parts of a section that cool fast enough will form martensite in a thick section it will only form to a certain depth and if the shape is complex it may only form in small pockets The hardness of martensite is solely dependant on carbon content it is normally very high unless the carbon content is exceptionally low The martensitic transformation is of great practical significance since it is the martensite which gives steel its high degree of hardness and strength
In the induction hardening of our interest the surface of the workpiece is heated up over the austenitization temperature by the induction heating Figure 12 and transformed from the ferritic and pearlitic structure Figure 14 A to the austenite structure Figure 14 B The heating process is then followed by immediate quenching process Figure 13 and the surface of the workpiece is transformed from the austenitic to the martensitic phase Figure 14 C and thereby hardened The heating condition for the induction hardening can be determined experimentally or empirically for the workpiece of any shape [1]
Figure 14 Specimen microstructures of normalized steel A) Ferritic-Pearlitic B) Austenitic and C) Martensitic
9
Induction heating is the process of heating an electrically conducting object by electromagnetic induction where eddy currents are generated within the metal and resistance leads to Joule heating of the metal [6] This process is widely used in industrial operations due to its high efficiency precise control and more environmentally friendly properties [3] The induction heating has some characteristics compared to the traditional heating methods (such as furnace heating)
It has a precise depth of heating and the heating zone which is easier to control
It is easy to implement high power density fast heating high efficiency and low energy consumption
It is easy to control the high heating temperature
The conduction and infiltration of the heating temperature will be from the surface to the interior
There are no penetrating impurities since non-contact heating method is used
The burned part on the workpiece is smaller
The process is somewhat eco-friendly
It is easy to accomplish the automation of heating process
The quenching part of an induction hardening process is also an important part Cooling rates must be rapid in order to avoid softer undesirable structures such as pearlite and bainite Due to its importance the cooling portion of the induction hardening process deserves careful consideration particularly when specifying new induction equipment and processes Process parameters must be precisely controlled to assure consistent heat treatment results Excessive variation in these parameters will cause undesirable or inconsistent process results including problems with case depth hardness pattern and distortion [4] Water quench has been used for the problem in this thesis
12 Aim
Let us go to the main objective of this work Although the induction hardening process has many advantages the design of it which is usually based on experiments can be tiresome time-consuming and expensive
10
Luckily the fast development of the computer technology makes it possible to model the induction heat treatment process with numerical tools particularly with Finite Element Method (FEM) Nowadays a lot of engineers pay attention to this area
There are many FEM modeling works regarding either the heating or quenching heat treatment in the literature However numerical models of the integrated heat treatment ie both the induction heating and quenching are still gaining ground [5] Induction hardening is a complex physical process which has contributions from electrical magnetic thermal mechanical and metallurgical processes It is obvious that the complexity of the phenomena ndash including phase transformation and heat exchange makes the FEM analysis heavy and difficult
Different FEM softwares have been used for numerical studies of the induction hardening process In this study LS-DYNA has been used for simulations The electromagnetic field the eddy current and the temperature field have been calculated with the FEM and Boundary Element Method (BEM) In fact FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air thus no air mesh is needed The main study included
The mathematical description and the modeling of the induction heat treatment process
Solving the induction-hardening-modeling key technical issues
Simulating the induction hardening process with the existing commercial software LS-DYNA
Comparing the results of the simulation with the literature values and evaluating the softwarersquos capability
In short the aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The simulation results have been compared to literature results for evaluation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Here follows the model selected from a literature source [5] the induction heating and cooling of cylindrical workpiece The experimental setup is made of three parts the coil the bar and the cooling tool Figure 15
11
Figure 15 The experimental set-up
12
2 Induction and the corresponding numerical background
21 Induction process - Maxwell equations
The basic model is shown in Figure 21
Figure 21 Induction heating principle
The partial differential equations are used to solve the electromagnetic field distribution
In order to define the equations solved by the electromagnetic solver in LS-DYNA we start with the Maxwell equations [7]
t
BE
(21)
t
EjH
0 (22)
0 B
(23)
13
0
E
(24)
sjEj
(25)
HB
0 (26)
where E
is electric field B
is magnetic flux density t is time H
is
magnetic field intensity j
is current density 0 is permittivity of free
space is total charge density is electric conductivity sj
is source
current density and 0 is permeability of free space
The eddy current approximation used here implies a divergence-free current
density and no charge accumulation thus resulting in 00
t
E
and 0
Equations (22) and (24) in the eddy current approximation give
jH
(27)
0 E
(28)
0 j
(29)
The divergence condition given by equation (23) allows writing B
as
AB
(210)
where A
is the magnetic vector potential [8] Equation (21) then implies that the electric field is given by
t
AE
(211)
14
where is the electric scalar potential
Equation (210) leaves a mathematical degree of freedom to A
(if A
is
transformed to a given
A then Equation (210) remains valid) Therefore the introduction of a gauge ie a particular choice of the scalar and vector potentials is needed Gauge choosing denotes a mathematical procedure for coping with redundant degrees of freedom in field variables The gauge chosen here is the generalized Coulomb gauge
0 A
(212)
Equations (25) (29) (211) and (212) give
0
(213)
Equations (25) (27) (211) and (210) give
sjAt
A
1
(214)
Equation (213) and Equation (214) are the two equations constituting the system that will be solved where A
and are the two unknowns of the
problem [7]
211 Skin effect and skin depth
Skin effect is the tendency of an alternating electric current (AC) to become distributed within a conductor such that the current density is largest near the surface of the conductor and decreases with greater depths in the conductor [9]
Skin effect is associated with the current flowing mainly at the skin of the conductor at an average depth called the skin depth The skin depth is
15
defined as the depth at which the electromagnetic field in a conducting material has decreased to 037 of its value just outside the material which describes the electric and magnetic fields The formula for the skin depth is given by
ff rr
503
)2(
22
0
(215)
where is the skin depth f is the frequency is the average electrical
resistivity and r is the average relative permeability
212 Proximity effect
A changing magnetic field will influence the distribution of an electric current flowing within an electrical conductor by electromagnetic induction When an alternating current flows through an isolated conductor it creates an associated alternating magnetic field around it The alternating magnetic field induces eddy currents in adjacent conductors altering the overall distribution of current flowing through them ndash the distribution of current within the conductor will be constrained to smaller regions Subsequently the resistance is increased in those regions The resulting current crowding is termed the proximity effect Usually the current is concentrated in the areas of the conductor furthest away from nearby conductors carrying current in the same direction [10]
Thus since in our case the inductor is a coil the maximum current density will be at the inner side of the coil [3] So the inner side of the coil will be used to heat the workpiece which will get faster temperature increase and will be more efficient
22 Numerical basis of the induction process
All the physical phenomena encountered in engineering mechanics are modeled by differential equations Usually it is difficult to obtain accurate analytical solution of the differential equation However the numerical solution could be calculated but only when boundary conditions and initial
16
conditions under specific situations were given The following numerical methods are used to model the induction process in LS-DYNA
Finite Element Method
The FEM is today a powerful (often the most powerful) tool for numerical solution of any differential equation whether this arises from structural mechanics fluid mechanics thermodynamics biology ecology or any other field of science [11]
The finite element method is a numerical approach by which general differential equations can be solved in an approximate manner [12] A domain of interest is represented as an assembly of finite elements The FEM is useful for problems with complicated geometries loadings and material properties where analytical solutions cannot be obtained [13]
The main steps in the general FE formulation and solution of a physical problem are [11]
o Establish the strong form of the governing differential equation
o Transform this differential equation into the weak form
o Choose trial functions for the unknown function that is choose element type(s) and mesh the solution domain
o Choose weight functions and establish the system of algebraic equations for each element (element equations)
o Assemble these element systems into the global system of algebraic equations
o Introduce boundary conditions into the global system of algebraic equations
o Solve the system of algebraic equations and present the results or use them for further calculations
Boundary Element Method
The boundary element method (BEM) is a numerical computational method of solving linear partial differential equations which have been formulated as integral equations BEM attempts to use the given boundary conditions to fit only boundary values into the integral equation Once this is done the integral equation can then be used again to calculate numerically solution at any desired point in the interior of the solution domain The boundary
17
element method is often more efficient than other methods including FEM in terms of computational resources for problems where there is a small surfacevolume ratio Conceptually it works by constructing a mesh over the modeled surface However for many problems boundary element methods are significantly less suitable and efficient than volume-discretization methods [14]
In numerical computations of the problem in this thesis with LS-DYNA FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air
221 FEM model for electromagnetic field
In LS-DYNA equation (213) is projected on the 0W forms (0-forms are continuous scalar basis functions that have a well defined gradient the gradient of a 0-form being a 1- form) and equation (214) is projected on
the 1W
forms (1-forms are vector basis functions with continuous tangential components but discontinuous normal components) They have a well defined curl the curl of a 1-form being a 2-form) giving after integrating by part the following weak formulations [15]
00 dW
(216)
dWAndW
dWAdWt
A
11
11
)(
1
(217)
where d an element of volume and the surface of with n
outer normal to
The and A
decompositions on respectfully 0W and 1W
give
0iiw (218)
1iiwaA
(219)
18
When replacing and A
in equation (216) and (217) by (218) and (219) one gets
0)(0 S (220)
SaDaSt
aM
)()
1()( 0111
(221)
where
the stiffness matrix of the 0-forms is given by
dWWjiS ji000 ))((
(222)
the mass matrix of the 1-forms is given by
dWWjiM ji111 ))((
(223)
the stiffness matrix of the 1-forms is given by
dWWjiS ji )()(1
))(1
( 111
(224)
the derivative matrix of the 0-1-forms is given by
dWWjiD ji )())(( 1001
(225)
the outside stiffness matrix is given by
19
dWWnjiS ji11)(
1))(
1(
(226)
where is the magnetic permeability n
is the normal vector is the volume and is the boundary surface of volume
Equation (220) and (221) form the FEM system with and a being the unknowns From this system only the outside stiffness matrix cannot be directly computed The calculation of this matrix will be made possible through the definition of the BEM system [7] The BEM system is used for the air and will not be shown in this report More information about it could be found in [7]
222 FEM model for temperature field
The steady state or transient temperature field on three dimensional geometries can also be solved by LS-DYNA Material properties may be temperature dependent and either isotopic or orthotropic A variety of time and temperature dependent boundary conditions can be specified including temperature flux convection and radiation The implementation of heat conduction into LS-DYNA is based on the work of Shapiro [16]
The differential equations of conduction of heat in a three-dimensional continuum is given by
Qkt
cijij
(227)
where )( txi is temperature )( ix is density )( ixcc is
the specific heat )( iijij xkk is thermal conductivity )( ixQQ is
internal heat generation rate per unit volume
The boundary conditions are
s on 1 (228)
20
ijij nk on 2 (229)
Initial conditions at 0t are given by
)(0 ix at 0tt (230)
where )(txx ii are coordinates as a function of time is prescribed
temperature on 1 and in is normal vector to 2
Equations (227-230) represent the strong form of a boundary value problem to be solved for the temperature field within the solid continuum [16]
The finite element method provides the following equations for the numerical solution of equations (227-230)
nnnnnnn HFHt
C
1 (231)
e
jie
eij
e
dcNNCC (232)
ejiji
T
e
eij
ee
dNNdNKNHH (233)
eigi
e
ei
ee
dNdqNFF (234)
where and are the parameters that are different when using different methods like Crank-Nicolson Galerkin and so on The parameter is taken to be in the interval [01] C H and F are the element stiffness load and boundary matrices respectively N is the element shape functions gq is the heat flow K is the thermal conductivity tensor
21
The boundary conditions for temperature flux convection and radiation are
)(
)(
)(
42
4112 TTF
n
T
TThn
T
qn
Tk
tzyxfT
w
sz
(235)
where T is the temperature k is the thermal conductivity n is the normal direction of the boundary szq
is the heat flux vector h is the convective
heat transfer coefficient wT is the surface temperature of the solid T is
the fluid temperature is the emissivity is the Stefan Boltzmann constant
223 FEM model for mechanical field
The equations that govern analyses of the behavior of a solid continuum are those of momentum conservation ie the equations of motion For an analysis of small deformation of a solid continuum these are (in tensor form) [17]
iijij ub (236)
where ij is the Cauchy stress tensor ib the body force vector per unit
volume the density and iu the displacement vector
To establish a weak form from the strong one we multiply (236) by an arbitrary velocity ie the test function iv and integrate over the region
By introducing two boundary conditions ii uu on u and ijijn on
where 0v on u the above differential equation in the weak form
[17] is given as
22
dvdbvduvdv iiiiiiijji (237)
To perform the FE discretization of the weak form (237) means to divide the continuum volume into sub-elements where the displacement field in every element is approximated by shape functions )(xNI and nodal
displacements )(tuiI that is summation of their products [17]
)()()( xNtutxu IiIi (238)
By approximating the test functions with the same shape functions (Galerkin method) we obtain
0)(
)()(
)(
)(
)(
)(
int)(
int
int
ee
e
e
dNbdNff
NdNMM
x
NBdBff
fuMfv
TTexte
ext
Te
j
IjI
Te
extT
(239)
which must hold for an arbitrary v and which puts the FE equation in order
intffuM ext (240)
For a linear material C the FE equation that emerges is
23
)(
)(e
dCBBKKfKuuM TTeext (241)
224 Numerical procedure
For the induction hardening process three different analyses have been combined in one numerical procedure mechanical thermal-metallurgical and electromagnetic (EM) computations They are solved fully transiently Boundary conditions and material properties beside one unique geometric model were required by each of them
What is necessary to mention is that some characteristics of the material are interdependent The electric conductivity for instance depends on the temperature In addition all thermal properties depend on the temperature [18] The variation of the properties with the temperature makes the system to be non-linear
There is a high coupling grade between thermal and EM equations because the electrical and magnetic properties laws depend on temperature When the initial temperature is known the eddy current value is calculated and then used to compute the heat generated by the Joule effect [5] At each time step the convergence is checked Until a steady state between the heat and the temperature field is reached the temperature value will be recalculated for each magnetic sub-step
EM solver can be coupled with the thermal and mechanical solvers in order to take full advantage of their capabilities [7] Both the thermal and the EM solver run with implicit time integration For mechanical solver there are two time integration methods of explicit and implicit type
Explicit and implicit methods are numerical schemes for obtaining numerical solutions of time-dependent ordinary and partial differential equations as is required in computer simulations of physical processes Explicit methods calculate the state of a system at a later time from the state of the system at the current time while implicit methods find a solution by solving an equation involving both the current state of the system and the later one [19] Here follows the difference between explicit and implicit methods
Implicit method
o More accurate
24
o It has large time step increment
o Convergence of each load step can be controlled to avoid error accumulation
o Iteration may not converge
Explicit method
o Less accurate
o It has small time step
o There is error accumulation and the error is difficult to estimate
o Iteration converges
However the implicit type has been governing the mechanical solver for the induction process in this thesis
Now let us go back to the couplings For the electromagnetic and structure interaction both the mechanical and the EM solver have distinct time steps By linear interpolation the EM fields are evaluated at the mechanical time step The two solvers will interact at each electromagnetic time step The EM solver will communicate the Lorentz force to the mechanical solver [7] resulting in an extra force in the mechanic equation
Lorentzext FfDt
Du (242)
where is total charge density is electrical conductivity extf is the
external force while LorentzF is the Lorentz force In turn the displacements
and deformations of the conductors are returned by the mechanical solver
When it comes to the thermal coupling at each electromagnetic time step the EM solver will communicate the extra Joule heating power term and the thermal solver will communicate the temperature
Figure 22 shows the interactions between the different solvers in LS-DYNA
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
1
Acknowledgements
The research work was carried out at SKF AB Manufacturing Development Center during the spring and summer 2013 The thesis is the concluding part of an engineering degree from Department of Mechanical Engineering Blekinge Institute of Technology (BTH) Karlskrona Sweden
First of all I would like to express my sincere gratitude to my supervisors at SKF Edin Omerspahic and John Lorentzon Without their support and enthusiasm the thesis will never come out Their guidance insight conversations timely advices and comments have been a source of strength to me
Many thanks also to Marcus Lilja and Mikael Schill at DYNAMORE and Vinayak Deshmukh and Johan Facht at SKF who always helped me when I was in trouble during the research work
I would also like to thank Ansel Berghuvud my Supervisor at Blekinge Institute of Technology who supported me a lot during this thesis work
Finally I would like to thank all friends and staff at SKF for their valuable input to the thesis and their help
Goumlteborg September 2013
Heng Liu
2
Contents
Notation 3 1 Introduction 6
11 Background 6 12 Aim 9
2 Induction and the corresponding numerical background 12 21 Induction process - Maxwell equations 12
211 Skin effect and skin depth 14 212 Proximity effect 15
22 Numerical basis of the induction process 15 221 FEM model for electromagnetic field 17 222 FEM model for temperature field 19 223 FEM model for mechanical field 21 224 Numerical procedure 23
23 Microstructures in numerical model 26 24 Numerical determination of hardness 29
3 Simulation (FEM) model 31 31 Initial and boundary conditions 31 32 Meshing 33 33 Material properties 34
331 Thermal and electromagnetic properties of the bar 34 332 Mechanical and metallurgical properties of the bar 37 333 Material properties of the inductor 38
34 Limitations 38 4 Analysis and discussion of the simulation results 40
41 Magnetic results 41 42 Thermal results 44 43 Metallurgical results 45
5 Evaluation of the results 50 6 Conclusions 54 Reference 55 Appendix A Miscellaneous results 57
Explicit mechanical solver 57 Implicit mechanical solver with curve switching between heating and
cooling 58 Implicit mechanical solver with 2 successive processes ndash heating and
cooling enabled by INTERFACE_SPRINGBACK_LSDYNA 60
3
Notation
A
Vector Potential [Tm]
a u Acceleration [ms2]
B
Magnetic flux density [T]
b Material coefficient [-]
C Specific Heat [Jkg K]
cC Capacitance [F]
pC Chemical composition []
c Empirical grain growth parameter [-]
dc Damping coefficient [N sm]
E Youngrsquos Modulus [Pa]
E
Electric field [Vm]
LorentzF Lorentz force [N]
f Frequency [kHz]
Df Damping force [N]
lf Inertial force [N]
Sf Elastic force [N]
G Energy release rate [Jm2]
gG Grain number [-]
H
Magnetic field intensity [Am]
Hv Hardness [-]
h Convection coefficient [W(m2K)]
I Current [A]
j
Current density [Am2]
sj
Source current density [Am2]
k Thermal conductivity [W(m K)]
4
sk Linear stiffness [Nm]
L Inductance [H]
m Mass [kg]
Ms temperature of the initial martensitic
transformation [K]
n Normal direction of the boundary [-]
p Phase proportion [-]
eqp Phase proportion calculated at thermodynamic equilibrium
[-]
Q Internal heat generation rate per unit volume [-]
kQ Activation energy [J]
q Charge [C]
szq
Heat flux vector [-]
R Resistance [Ω]
bR Radius [m]
uR Universal gas constant [J(mol K)]
r Position [m]
T Temperature [K]
wT Surface temperature of the solid [K]
T Fluid temperature [K]
t Time [sec]
u Displacement [m]
u v Velocity [ms]
V Voltage amplitude [V]
Vr Cooling rate at 700 [Ks]
kX Actual phase [-]
kx True amount of phase [-]
Material dependent constant [-]
Stress [Pa]
B Stefan Boltzmann constant [W(m2K4)]
5
C Electric conductivity [1(Ωm)]
Strain []
0 Permittivity of free space [Fm]
e Surface emissivity [-]
Scalar Potential [V]
Skin depth [m]
Magnetic Permeability [Hm]
0 Permeability of free space [Hm]
r Relative permeability [-]
Density [kgm3]
c Total Charge density [Cm3]
e Electrical resistivity [Ωm]
Shear stress [Pa]
R Delay time of the transformation [sec]
Poissons ratio [-]
Volume [m3]
Boundary surface of volume [m2]
Pulsation [rads]
6
1 Introduction
11 Background
The induction hardening is one of the methods for heat treatment of steel workpieces The induction hardening can be used for both through-hardening and to selectively harden areas of a part or assembly When the method is used to harden only the surface of the parts it has been applied to various machine parts such as automobile components and toothed gears [1]
The classic method of hardening contains first heating to an austenitic state (austenite has a Face Centre Cubic ndash FCC atomic structure) and then cooling rapidly Let us assume the initial phase being ferritic-pearlitic Ferrite has a Body Centre Cubic structure (BCC) which can hold very little carbon typically 00001 at room temperature It can exist as either alpha or delta ferrite Pearlite is a mixture of alternate strips of ferrite and cementite in a single grain The name for this structure is derived from pearl appearance seen under a microscope A fully pearlitic structure occurs at 08 Carbon
During heating see Figure 12 two processes occur Firstly the cementite starts to dissolve and the cementite particles to shrink When the temperature rises above a critical value the ferrite starts to transform to austenite Austenite formation and cementite dissolution occur faster the higher the temperature The structure is fully austenitic above the A3 (Ac3) or Accm line (the upper line in the Iron Carbon Diagram) Figure 11
7
Figure 11 Iron Carbon Diagram
Figure 12 Induction heating of a part
During cooling from the austenitic state several different phase transformations may take place depending on how fast the cooling process is When steel is cooled sufficiently rapidly other structures do not have sufficient time to form and the austenite can be retained at low temperatures since the diffusion-dependent transformations proceed slowly When the temperature is sufficiently low the tendency of austenite to be transformed becomes so strong that the transformation takes place without diffusion Such a transformation is called diffusionless and can in principle occur with two different mechanisms namely massive and martensitic transformation [2]
Figure 13 Quenching (cooling) of a part
8
In a martensitic transformation FCC structure of austenite rapidly changes to BCC leaving insufficient time for the carbon to form pearlite This results in a distorted structure that has the appearance of fine needles Only the parts of a section that cool fast enough will form martensite in a thick section it will only form to a certain depth and if the shape is complex it may only form in small pockets The hardness of martensite is solely dependant on carbon content it is normally very high unless the carbon content is exceptionally low The martensitic transformation is of great practical significance since it is the martensite which gives steel its high degree of hardness and strength
In the induction hardening of our interest the surface of the workpiece is heated up over the austenitization temperature by the induction heating Figure 12 and transformed from the ferritic and pearlitic structure Figure 14 A to the austenite structure Figure 14 B The heating process is then followed by immediate quenching process Figure 13 and the surface of the workpiece is transformed from the austenitic to the martensitic phase Figure 14 C and thereby hardened The heating condition for the induction hardening can be determined experimentally or empirically for the workpiece of any shape [1]
Figure 14 Specimen microstructures of normalized steel A) Ferritic-Pearlitic B) Austenitic and C) Martensitic
9
Induction heating is the process of heating an electrically conducting object by electromagnetic induction where eddy currents are generated within the metal and resistance leads to Joule heating of the metal [6] This process is widely used in industrial operations due to its high efficiency precise control and more environmentally friendly properties [3] The induction heating has some characteristics compared to the traditional heating methods (such as furnace heating)
It has a precise depth of heating and the heating zone which is easier to control
It is easy to implement high power density fast heating high efficiency and low energy consumption
It is easy to control the high heating temperature
The conduction and infiltration of the heating temperature will be from the surface to the interior
There are no penetrating impurities since non-contact heating method is used
The burned part on the workpiece is smaller
The process is somewhat eco-friendly
It is easy to accomplish the automation of heating process
The quenching part of an induction hardening process is also an important part Cooling rates must be rapid in order to avoid softer undesirable structures such as pearlite and bainite Due to its importance the cooling portion of the induction hardening process deserves careful consideration particularly when specifying new induction equipment and processes Process parameters must be precisely controlled to assure consistent heat treatment results Excessive variation in these parameters will cause undesirable or inconsistent process results including problems with case depth hardness pattern and distortion [4] Water quench has been used for the problem in this thesis
12 Aim
Let us go to the main objective of this work Although the induction hardening process has many advantages the design of it which is usually based on experiments can be tiresome time-consuming and expensive
10
Luckily the fast development of the computer technology makes it possible to model the induction heat treatment process with numerical tools particularly with Finite Element Method (FEM) Nowadays a lot of engineers pay attention to this area
There are many FEM modeling works regarding either the heating or quenching heat treatment in the literature However numerical models of the integrated heat treatment ie both the induction heating and quenching are still gaining ground [5] Induction hardening is a complex physical process which has contributions from electrical magnetic thermal mechanical and metallurgical processes It is obvious that the complexity of the phenomena ndash including phase transformation and heat exchange makes the FEM analysis heavy and difficult
Different FEM softwares have been used for numerical studies of the induction hardening process In this study LS-DYNA has been used for simulations The electromagnetic field the eddy current and the temperature field have been calculated with the FEM and Boundary Element Method (BEM) In fact FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air thus no air mesh is needed The main study included
The mathematical description and the modeling of the induction heat treatment process
Solving the induction-hardening-modeling key technical issues
Simulating the induction hardening process with the existing commercial software LS-DYNA
Comparing the results of the simulation with the literature values and evaluating the softwarersquos capability
In short the aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The simulation results have been compared to literature results for evaluation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Here follows the model selected from a literature source [5] the induction heating and cooling of cylindrical workpiece The experimental setup is made of three parts the coil the bar and the cooling tool Figure 15
11
Figure 15 The experimental set-up
12
2 Induction and the corresponding numerical background
21 Induction process - Maxwell equations
The basic model is shown in Figure 21
Figure 21 Induction heating principle
The partial differential equations are used to solve the electromagnetic field distribution
In order to define the equations solved by the electromagnetic solver in LS-DYNA we start with the Maxwell equations [7]
t
BE
(21)
t
EjH
0 (22)
0 B
(23)
13
0
E
(24)
sjEj
(25)
HB
0 (26)
where E
is electric field B
is magnetic flux density t is time H
is
magnetic field intensity j
is current density 0 is permittivity of free
space is total charge density is electric conductivity sj
is source
current density and 0 is permeability of free space
The eddy current approximation used here implies a divergence-free current
density and no charge accumulation thus resulting in 00
t
E
and 0
Equations (22) and (24) in the eddy current approximation give
jH
(27)
0 E
(28)
0 j
(29)
The divergence condition given by equation (23) allows writing B
as
AB
(210)
where A
is the magnetic vector potential [8] Equation (21) then implies that the electric field is given by
t
AE
(211)
14
where is the electric scalar potential
Equation (210) leaves a mathematical degree of freedom to A
(if A
is
transformed to a given
A then Equation (210) remains valid) Therefore the introduction of a gauge ie a particular choice of the scalar and vector potentials is needed Gauge choosing denotes a mathematical procedure for coping with redundant degrees of freedom in field variables The gauge chosen here is the generalized Coulomb gauge
0 A
(212)
Equations (25) (29) (211) and (212) give
0
(213)
Equations (25) (27) (211) and (210) give
sjAt
A
1
(214)
Equation (213) and Equation (214) are the two equations constituting the system that will be solved where A
and are the two unknowns of the
problem [7]
211 Skin effect and skin depth
Skin effect is the tendency of an alternating electric current (AC) to become distributed within a conductor such that the current density is largest near the surface of the conductor and decreases with greater depths in the conductor [9]
Skin effect is associated with the current flowing mainly at the skin of the conductor at an average depth called the skin depth The skin depth is
15
defined as the depth at which the electromagnetic field in a conducting material has decreased to 037 of its value just outside the material which describes the electric and magnetic fields The formula for the skin depth is given by
ff rr
503
)2(
22
0
(215)
where is the skin depth f is the frequency is the average electrical
resistivity and r is the average relative permeability
212 Proximity effect
A changing magnetic field will influence the distribution of an electric current flowing within an electrical conductor by electromagnetic induction When an alternating current flows through an isolated conductor it creates an associated alternating magnetic field around it The alternating magnetic field induces eddy currents in adjacent conductors altering the overall distribution of current flowing through them ndash the distribution of current within the conductor will be constrained to smaller regions Subsequently the resistance is increased in those regions The resulting current crowding is termed the proximity effect Usually the current is concentrated in the areas of the conductor furthest away from nearby conductors carrying current in the same direction [10]
Thus since in our case the inductor is a coil the maximum current density will be at the inner side of the coil [3] So the inner side of the coil will be used to heat the workpiece which will get faster temperature increase and will be more efficient
22 Numerical basis of the induction process
All the physical phenomena encountered in engineering mechanics are modeled by differential equations Usually it is difficult to obtain accurate analytical solution of the differential equation However the numerical solution could be calculated but only when boundary conditions and initial
16
conditions under specific situations were given The following numerical methods are used to model the induction process in LS-DYNA
Finite Element Method
The FEM is today a powerful (often the most powerful) tool for numerical solution of any differential equation whether this arises from structural mechanics fluid mechanics thermodynamics biology ecology or any other field of science [11]
The finite element method is a numerical approach by which general differential equations can be solved in an approximate manner [12] A domain of interest is represented as an assembly of finite elements The FEM is useful for problems with complicated geometries loadings and material properties where analytical solutions cannot be obtained [13]
The main steps in the general FE formulation and solution of a physical problem are [11]
o Establish the strong form of the governing differential equation
o Transform this differential equation into the weak form
o Choose trial functions for the unknown function that is choose element type(s) and mesh the solution domain
o Choose weight functions and establish the system of algebraic equations for each element (element equations)
o Assemble these element systems into the global system of algebraic equations
o Introduce boundary conditions into the global system of algebraic equations
o Solve the system of algebraic equations and present the results or use them for further calculations
Boundary Element Method
The boundary element method (BEM) is a numerical computational method of solving linear partial differential equations which have been formulated as integral equations BEM attempts to use the given boundary conditions to fit only boundary values into the integral equation Once this is done the integral equation can then be used again to calculate numerically solution at any desired point in the interior of the solution domain The boundary
17
element method is often more efficient than other methods including FEM in terms of computational resources for problems where there is a small surfacevolume ratio Conceptually it works by constructing a mesh over the modeled surface However for many problems boundary element methods are significantly less suitable and efficient than volume-discretization methods [14]
In numerical computations of the problem in this thesis with LS-DYNA FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air
221 FEM model for electromagnetic field
In LS-DYNA equation (213) is projected on the 0W forms (0-forms are continuous scalar basis functions that have a well defined gradient the gradient of a 0-form being a 1- form) and equation (214) is projected on
the 1W
forms (1-forms are vector basis functions with continuous tangential components but discontinuous normal components) They have a well defined curl the curl of a 1-form being a 2-form) giving after integrating by part the following weak formulations [15]
00 dW
(216)
dWAndW
dWAdWt
A
11
11
)(
1
(217)
where d an element of volume and the surface of with n
outer normal to
The and A
decompositions on respectfully 0W and 1W
give
0iiw (218)
1iiwaA
(219)
18
When replacing and A
in equation (216) and (217) by (218) and (219) one gets
0)(0 S (220)
SaDaSt
aM
)()
1()( 0111
(221)
where
the stiffness matrix of the 0-forms is given by
dWWjiS ji000 ))((
(222)
the mass matrix of the 1-forms is given by
dWWjiM ji111 ))((
(223)
the stiffness matrix of the 1-forms is given by
dWWjiS ji )()(1
))(1
( 111
(224)
the derivative matrix of the 0-1-forms is given by
dWWjiD ji )())(( 1001
(225)
the outside stiffness matrix is given by
19
dWWnjiS ji11)(
1))(
1(
(226)
where is the magnetic permeability n
is the normal vector is the volume and is the boundary surface of volume
Equation (220) and (221) form the FEM system with and a being the unknowns From this system only the outside stiffness matrix cannot be directly computed The calculation of this matrix will be made possible through the definition of the BEM system [7] The BEM system is used for the air and will not be shown in this report More information about it could be found in [7]
222 FEM model for temperature field
The steady state or transient temperature field on three dimensional geometries can also be solved by LS-DYNA Material properties may be temperature dependent and either isotopic or orthotropic A variety of time and temperature dependent boundary conditions can be specified including temperature flux convection and radiation The implementation of heat conduction into LS-DYNA is based on the work of Shapiro [16]
The differential equations of conduction of heat in a three-dimensional continuum is given by
Qkt
cijij
(227)
where )( txi is temperature )( ix is density )( ixcc is
the specific heat )( iijij xkk is thermal conductivity )( ixQQ is
internal heat generation rate per unit volume
The boundary conditions are
s on 1 (228)
20
ijij nk on 2 (229)
Initial conditions at 0t are given by
)(0 ix at 0tt (230)
where )(txx ii are coordinates as a function of time is prescribed
temperature on 1 and in is normal vector to 2
Equations (227-230) represent the strong form of a boundary value problem to be solved for the temperature field within the solid continuum [16]
The finite element method provides the following equations for the numerical solution of equations (227-230)
nnnnnnn HFHt
C
1 (231)
e
jie
eij
e
dcNNCC (232)
ejiji
T
e
eij
ee
dNNdNKNHH (233)
eigi
e
ei
ee
dNdqNFF (234)
where and are the parameters that are different when using different methods like Crank-Nicolson Galerkin and so on The parameter is taken to be in the interval [01] C H and F are the element stiffness load and boundary matrices respectively N is the element shape functions gq is the heat flow K is the thermal conductivity tensor
21
The boundary conditions for temperature flux convection and radiation are
)(
)(
)(
42
4112 TTF
n
T
TThn
T
qn
Tk
tzyxfT
w
sz
(235)
where T is the temperature k is the thermal conductivity n is the normal direction of the boundary szq
is the heat flux vector h is the convective
heat transfer coefficient wT is the surface temperature of the solid T is
the fluid temperature is the emissivity is the Stefan Boltzmann constant
223 FEM model for mechanical field
The equations that govern analyses of the behavior of a solid continuum are those of momentum conservation ie the equations of motion For an analysis of small deformation of a solid continuum these are (in tensor form) [17]
iijij ub (236)
where ij is the Cauchy stress tensor ib the body force vector per unit
volume the density and iu the displacement vector
To establish a weak form from the strong one we multiply (236) by an arbitrary velocity ie the test function iv and integrate over the region
By introducing two boundary conditions ii uu on u and ijijn on
where 0v on u the above differential equation in the weak form
[17] is given as
22
dvdbvduvdv iiiiiiijji (237)
To perform the FE discretization of the weak form (237) means to divide the continuum volume into sub-elements where the displacement field in every element is approximated by shape functions )(xNI and nodal
displacements )(tuiI that is summation of their products [17]
)()()( xNtutxu IiIi (238)
By approximating the test functions with the same shape functions (Galerkin method) we obtain
0)(
)()(
)(
)(
)(
)(
int)(
int
int
ee
e
e
dNbdNff
NdNMM
x
NBdBff
fuMfv
TTexte
ext
Te
j
IjI
Te
extT
(239)
which must hold for an arbitrary v and which puts the FE equation in order
intffuM ext (240)
For a linear material C the FE equation that emerges is
23
)(
)(e
dCBBKKfKuuM TTeext (241)
224 Numerical procedure
For the induction hardening process three different analyses have been combined in one numerical procedure mechanical thermal-metallurgical and electromagnetic (EM) computations They are solved fully transiently Boundary conditions and material properties beside one unique geometric model were required by each of them
What is necessary to mention is that some characteristics of the material are interdependent The electric conductivity for instance depends on the temperature In addition all thermal properties depend on the temperature [18] The variation of the properties with the temperature makes the system to be non-linear
There is a high coupling grade between thermal and EM equations because the electrical and magnetic properties laws depend on temperature When the initial temperature is known the eddy current value is calculated and then used to compute the heat generated by the Joule effect [5] At each time step the convergence is checked Until a steady state between the heat and the temperature field is reached the temperature value will be recalculated for each magnetic sub-step
EM solver can be coupled with the thermal and mechanical solvers in order to take full advantage of their capabilities [7] Both the thermal and the EM solver run with implicit time integration For mechanical solver there are two time integration methods of explicit and implicit type
Explicit and implicit methods are numerical schemes for obtaining numerical solutions of time-dependent ordinary and partial differential equations as is required in computer simulations of physical processes Explicit methods calculate the state of a system at a later time from the state of the system at the current time while implicit methods find a solution by solving an equation involving both the current state of the system and the later one [19] Here follows the difference between explicit and implicit methods
Implicit method
o More accurate
24
o It has large time step increment
o Convergence of each load step can be controlled to avoid error accumulation
o Iteration may not converge
Explicit method
o Less accurate
o It has small time step
o There is error accumulation and the error is difficult to estimate
o Iteration converges
However the implicit type has been governing the mechanical solver for the induction process in this thesis
Now let us go back to the couplings For the electromagnetic and structure interaction both the mechanical and the EM solver have distinct time steps By linear interpolation the EM fields are evaluated at the mechanical time step The two solvers will interact at each electromagnetic time step The EM solver will communicate the Lorentz force to the mechanical solver [7] resulting in an extra force in the mechanic equation
Lorentzext FfDt
Du (242)
where is total charge density is electrical conductivity extf is the
external force while LorentzF is the Lorentz force In turn the displacements
and deformations of the conductors are returned by the mechanical solver
When it comes to the thermal coupling at each electromagnetic time step the EM solver will communicate the extra Joule heating power term and the thermal solver will communicate the temperature
Figure 22 shows the interactions between the different solvers in LS-DYNA
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
2
Contents
Notation 3 1 Introduction 6
11 Background 6 12 Aim 9
2 Induction and the corresponding numerical background 12 21 Induction process - Maxwell equations 12
211 Skin effect and skin depth 14 212 Proximity effect 15
22 Numerical basis of the induction process 15 221 FEM model for electromagnetic field 17 222 FEM model for temperature field 19 223 FEM model for mechanical field 21 224 Numerical procedure 23
23 Microstructures in numerical model 26 24 Numerical determination of hardness 29
3 Simulation (FEM) model 31 31 Initial and boundary conditions 31 32 Meshing 33 33 Material properties 34
331 Thermal and electromagnetic properties of the bar 34 332 Mechanical and metallurgical properties of the bar 37 333 Material properties of the inductor 38
34 Limitations 38 4 Analysis and discussion of the simulation results 40
41 Magnetic results 41 42 Thermal results 44 43 Metallurgical results 45
5 Evaluation of the results 50 6 Conclusions 54 Reference 55 Appendix A Miscellaneous results 57
Explicit mechanical solver 57 Implicit mechanical solver with curve switching between heating and
cooling 58 Implicit mechanical solver with 2 successive processes ndash heating and
cooling enabled by INTERFACE_SPRINGBACK_LSDYNA 60
3
Notation
A
Vector Potential [Tm]
a u Acceleration [ms2]
B
Magnetic flux density [T]
b Material coefficient [-]
C Specific Heat [Jkg K]
cC Capacitance [F]
pC Chemical composition []
c Empirical grain growth parameter [-]
dc Damping coefficient [N sm]
E Youngrsquos Modulus [Pa]
E
Electric field [Vm]
LorentzF Lorentz force [N]
f Frequency [kHz]
Df Damping force [N]
lf Inertial force [N]
Sf Elastic force [N]
G Energy release rate [Jm2]
gG Grain number [-]
H
Magnetic field intensity [Am]
Hv Hardness [-]
h Convection coefficient [W(m2K)]
I Current [A]
j
Current density [Am2]
sj
Source current density [Am2]
k Thermal conductivity [W(m K)]
4
sk Linear stiffness [Nm]
L Inductance [H]
m Mass [kg]
Ms temperature of the initial martensitic
transformation [K]
n Normal direction of the boundary [-]
p Phase proportion [-]
eqp Phase proportion calculated at thermodynamic equilibrium
[-]
Q Internal heat generation rate per unit volume [-]
kQ Activation energy [J]
q Charge [C]
szq
Heat flux vector [-]
R Resistance [Ω]
bR Radius [m]
uR Universal gas constant [J(mol K)]
r Position [m]
T Temperature [K]
wT Surface temperature of the solid [K]
T Fluid temperature [K]
t Time [sec]
u Displacement [m]
u v Velocity [ms]
V Voltage amplitude [V]
Vr Cooling rate at 700 [Ks]
kX Actual phase [-]
kx True amount of phase [-]
Material dependent constant [-]
Stress [Pa]
B Stefan Boltzmann constant [W(m2K4)]
5
C Electric conductivity [1(Ωm)]
Strain []
0 Permittivity of free space [Fm]
e Surface emissivity [-]
Scalar Potential [V]
Skin depth [m]
Magnetic Permeability [Hm]
0 Permeability of free space [Hm]
r Relative permeability [-]
Density [kgm3]
c Total Charge density [Cm3]
e Electrical resistivity [Ωm]
Shear stress [Pa]
R Delay time of the transformation [sec]
Poissons ratio [-]
Volume [m3]
Boundary surface of volume [m2]
Pulsation [rads]
6
1 Introduction
11 Background
The induction hardening is one of the methods for heat treatment of steel workpieces The induction hardening can be used for both through-hardening and to selectively harden areas of a part or assembly When the method is used to harden only the surface of the parts it has been applied to various machine parts such as automobile components and toothed gears [1]
The classic method of hardening contains first heating to an austenitic state (austenite has a Face Centre Cubic ndash FCC atomic structure) and then cooling rapidly Let us assume the initial phase being ferritic-pearlitic Ferrite has a Body Centre Cubic structure (BCC) which can hold very little carbon typically 00001 at room temperature It can exist as either alpha or delta ferrite Pearlite is a mixture of alternate strips of ferrite and cementite in a single grain The name for this structure is derived from pearl appearance seen under a microscope A fully pearlitic structure occurs at 08 Carbon
During heating see Figure 12 two processes occur Firstly the cementite starts to dissolve and the cementite particles to shrink When the temperature rises above a critical value the ferrite starts to transform to austenite Austenite formation and cementite dissolution occur faster the higher the temperature The structure is fully austenitic above the A3 (Ac3) or Accm line (the upper line in the Iron Carbon Diagram) Figure 11
7
Figure 11 Iron Carbon Diagram
Figure 12 Induction heating of a part
During cooling from the austenitic state several different phase transformations may take place depending on how fast the cooling process is When steel is cooled sufficiently rapidly other structures do not have sufficient time to form and the austenite can be retained at low temperatures since the diffusion-dependent transformations proceed slowly When the temperature is sufficiently low the tendency of austenite to be transformed becomes so strong that the transformation takes place without diffusion Such a transformation is called diffusionless and can in principle occur with two different mechanisms namely massive and martensitic transformation [2]
Figure 13 Quenching (cooling) of a part
8
In a martensitic transformation FCC structure of austenite rapidly changes to BCC leaving insufficient time for the carbon to form pearlite This results in a distorted structure that has the appearance of fine needles Only the parts of a section that cool fast enough will form martensite in a thick section it will only form to a certain depth and if the shape is complex it may only form in small pockets The hardness of martensite is solely dependant on carbon content it is normally very high unless the carbon content is exceptionally low The martensitic transformation is of great practical significance since it is the martensite which gives steel its high degree of hardness and strength
In the induction hardening of our interest the surface of the workpiece is heated up over the austenitization temperature by the induction heating Figure 12 and transformed from the ferritic and pearlitic structure Figure 14 A to the austenite structure Figure 14 B The heating process is then followed by immediate quenching process Figure 13 and the surface of the workpiece is transformed from the austenitic to the martensitic phase Figure 14 C and thereby hardened The heating condition for the induction hardening can be determined experimentally or empirically for the workpiece of any shape [1]
Figure 14 Specimen microstructures of normalized steel A) Ferritic-Pearlitic B) Austenitic and C) Martensitic
9
Induction heating is the process of heating an electrically conducting object by electromagnetic induction where eddy currents are generated within the metal and resistance leads to Joule heating of the metal [6] This process is widely used in industrial operations due to its high efficiency precise control and more environmentally friendly properties [3] The induction heating has some characteristics compared to the traditional heating methods (such as furnace heating)
It has a precise depth of heating and the heating zone which is easier to control
It is easy to implement high power density fast heating high efficiency and low energy consumption
It is easy to control the high heating temperature
The conduction and infiltration of the heating temperature will be from the surface to the interior
There are no penetrating impurities since non-contact heating method is used
The burned part on the workpiece is smaller
The process is somewhat eco-friendly
It is easy to accomplish the automation of heating process
The quenching part of an induction hardening process is also an important part Cooling rates must be rapid in order to avoid softer undesirable structures such as pearlite and bainite Due to its importance the cooling portion of the induction hardening process deserves careful consideration particularly when specifying new induction equipment and processes Process parameters must be precisely controlled to assure consistent heat treatment results Excessive variation in these parameters will cause undesirable or inconsistent process results including problems with case depth hardness pattern and distortion [4] Water quench has been used for the problem in this thesis
12 Aim
Let us go to the main objective of this work Although the induction hardening process has many advantages the design of it which is usually based on experiments can be tiresome time-consuming and expensive
10
Luckily the fast development of the computer technology makes it possible to model the induction heat treatment process with numerical tools particularly with Finite Element Method (FEM) Nowadays a lot of engineers pay attention to this area
There are many FEM modeling works regarding either the heating or quenching heat treatment in the literature However numerical models of the integrated heat treatment ie both the induction heating and quenching are still gaining ground [5] Induction hardening is a complex physical process which has contributions from electrical magnetic thermal mechanical and metallurgical processes It is obvious that the complexity of the phenomena ndash including phase transformation and heat exchange makes the FEM analysis heavy and difficult
Different FEM softwares have been used for numerical studies of the induction hardening process In this study LS-DYNA has been used for simulations The electromagnetic field the eddy current and the temperature field have been calculated with the FEM and Boundary Element Method (BEM) In fact FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air thus no air mesh is needed The main study included
The mathematical description and the modeling of the induction heat treatment process
Solving the induction-hardening-modeling key technical issues
Simulating the induction hardening process with the existing commercial software LS-DYNA
Comparing the results of the simulation with the literature values and evaluating the softwarersquos capability
In short the aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The simulation results have been compared to literature results for evaluation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Here follows the model selected from a literature source [5] the induction heating and cooling of cylindrical workpiece The experimental setup is made of three parts the coil the bar and the cooling tool Figure 15
11
Figure 15 The experimental set-up
12
2 Induction and the corresponding numerical background
21 Induction process - Maxwell equations
The basic model is shown in Figure 21
Figure 21 Induction heating principle
The partial differential equations are used to solve the electromagnetic field distribution
In order to define the equations solved by the electromagnetic solver in LS-DYNA we start with the Maxwell equations [7]
t
BE
(21)
t
EjH
0 (22)
0 B
(23)
13
0
E
(24)
sjEj
(25)
HB
0 (26)
where E
is electric field B
is magnetic flux density t is time H
is
magnetic field intensity j
is current density 0 is permittivity of free
space is total charge density is electric conductivity sj
is source
current density and 0 is permeability of free space
The eddy current approximation used here implies a divergence-free current
density and no charge accumulation thus resulting in 00
t
E
and 0
Equations (22) and (24) in the eddy current approximation give
jH
(27)
0 E
(28)
0 j
(29)
The divergence condition given by equation (23) allows writing B
as
AB
(210)
where A
is the magnetic vector potential [8] Equation (21) then implies that the electric field is given by
t
AE
(211)
14
where is the electric scalar potential
Equation (210) leaves a mathematical degree of freedom to A
(if A
is
transformed to a given
A then Equation (210) remains valid) Therefore the introduction of a gauge ie a particular choice of the scalar and vector potentials is needed Gauge choosing denotes a mathematical procedure for coping with redundant degrees of freedom in field variables The gauge chosen here is the generalized Coulomb gauge
0 A
(212)
Equations (25) (29) (211) and (212) give
0
(213)
Equations (25) (27) (211) and (210) give
sjAt
A
1
(214)
Equation (213) and Equation (214) are the two equations constituting the system that will be solved where A
and are the two unknowns of the
problem [7]
211 Skin effect and skin depth
Skin effect is the tendency of an alternating electric current (AC) to become distributed within a conductor such that the current density is largest near the surface of the conductor and decreases with greater depths in the conductor [9]
Skin effect is associated with the current flowing mainly at the skin of the conductor at an average depth called the skin depth The skin depth is
15
defined as the depth at which the electromagnetic field in a conducting material has decreased to 037 of its value just outside the material which describes the electric and magnetic fields The formula for the skin depth is given by
ff rr
503
)2(
22
0
(215)
where is the skin depth f is the frequency is the average electrical
resistivity and r is the average relative permeability
212 Proximity effect
A changing magnetic field will influence the distribution of an electric current flowing within an electrical conductor by electromagnetic induction When an alternating current flows through an isolated conductor it creates an associated alternating magnetic field around it The alternating magnetic field induces eddy currents in adjacent conductors altering the overall distribution of current flowing through them ndash the distribution of current within the conductor will be constrained to smaller regions Subsequently the resistance is increased in those regions The resulting current crowding is termed the proximity effect Usually the current is concentrated in the areas of the conductor furthest away from nearby conductors carrying current in the same direction [10]
Thus since in our case the inductor is a coil the maximum current density will be at the inner side of the coil [3] So the inner side of the coil will be used to heat the workpiece which will get faster temperature increase and will be more efficient
22 Numerical basis of the induction process
All the physical phenomena encountered in engineering mechanics are modeled by differential equations Usually it is difficult to obtain accurate analytical solution of the differential equation However the numerical solution could be calculated but only when boundary conditions and initial
16
conditions under specific situations were given The following numerical methods are used to model the induction process in LS-DYNA
Finite Element Method
The FEM is today a powerful (often the most powerful) tool for numerical solution of any differential equation whether this arises from structural mechanics fluid mechanics thermodynamics biology ecology or any other field of science [11]
The finite element method is a numerical approach by which general differential equations can be solved in an approximate manner [12] A domain of interest is represented as an assembly of finite elements The FEM is useful for problems with complicated geometries loadings and material properties where analytical solutions cannot be obtained [13]
The main steps in the general FE formulation and solution of a physical problem are [11]
o Establish the strong form of the governing differential equation
o Transform this differential equation into the weak form
o Choose trial functions for the unknown function that is choose element type(s) and mesh the solution domain
o Choose weight functions and establish the system of algebraic equations for each element (element equations)
o Assemble these element systems into the global system of algebraic equations
o Introduce boundary conditions into the global system of algebraic equations
o Solve the system of algebraic equations and present the results or use them for further calculations
Boundary Element Method
The boundary element method (BEM) is a numerical computational method of solving linear partial differential equations which have been formulated as integral equations BEM attempts to use the given boundary conditions to fit only boundary values into the integral equation Once this is done the integral equation can then be used again to calculate numerically solution at any desired point in the interior of the solution domain The boundary
17
element method is often more efficient than other methods including FEM in terms of computational resources for problems where there is a small surfacevolume ratio Conceptually it works by constructing a mesh over the modeled surface However for many problems boundary element methods are significantly less suitable and efficient than volume-discretization methods [14]
In numerical computations of the problem in this thesis with LS-DYNA FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air
221 FEM model for electromagnetic field
In LS-DYNA equation (213) is projected on the 0W forms (0-forms are continuous scalar basis functions that have a well defined gradient the gradient of a 0-form being a 1- form) and equation (214) is projected on
the 1W
forms (1-forms are vector basis functions with continuous tangential components but discontinuous normal components) They have a well defined curl the curl of a 1-form being a 2-form) giving after integrating by part the following weak formulations [15]
00 dW
(216)
dWAndW
dWAdWt
A
11
11
)(
1
(217)
where d an element of volume and the surface of with n
outer normal to
The and A
decompositions on respectfully 0W and 1W
give
0iiw (218)
1iiwaA
(219)
18
When replacing and A
in equation (216) and (217) by (218) and (219) one gets
0)(0 S (220)
SaDaSt
aM
)()
1()( 0111
(221)
where
the stiffness matrix of the 0-forms is given by
dWWjiS ji000 ))((
(222)
the mass matrix of the 1-forms is given by
dWWjiM ji111 ))((
(223)
the stiffness matrix of the 1-forms is given by
dWWjiS ji )()(1
))(1
( 111
(224)
the derivative matrix of the 0-1-forms is given by
dWWjiD ji )())(( 1001
(225)
the outside stiffness matrix is given by
19
dWWnjiS ji11)(
1))(
1(
(226)
where is the magnetic permeability n
is the normal vector is the volume and is the boundary surface of volume
Equation (220) and (221) form the FEM system with and a being the unknowns From this system only the outside stiffness matrix cannot be directly computed The calculation of this matrix will be made possible through the definition of the BEM system [7] The BEM system is used for the air and will not be shown in this report More information about it could be found in [7]
222 FEM model for temperature field
The steady state or transient temperature field on three dimensional geometries can also be solved by LS-DYNA Material properties may be temperature dependent and either isotopic or orthotropic A variety of time and temperature dependent boundary conditions can be specified including temperature flux convection and radiation The implementation of heat conduction into LS-DYNA is based on the work of Shapiro [16]
The differential equations of conduction of heat in a three-dimensional continuum is given by
Qkt
cijij
(227)
where )( txi is temperature )( ix is density )( ixcc is
the specific heat )( iijij xkk is thermal conductivity )( ixQQ is
internal heat generation rate per unit volume
The boundary conditions are
s on 1 (228)
20
ijij nk on 2 (229)
Initial conditions at 0t are given by
)(0 ix at 0tt (230)
where )(txx ii are coordinates as a function of time is prescribed
temperature on 1 and in is normal vector to 2
Equations (227-230) represent the strong form of a boundary value problem to be solved for the temperature field within the solid continuum [16]
The finite element method provides the following equations for the numerical solution of equations (227-230)
nnnnnnn HFHt
C
1 (231)
e
jie
eij
e
dcNNCC (232)
ejiji
T
e
eij
ee
dNNdNKNHH (233)
eigi
e
ei
ee
dNdqNFF (234)
where and are the parameters that are different when using different methods like Crank-Nicolson Galerkin and so on The parameter is taken to be in the interval [01] C H and F are the element stiffness load and boundary matrices respectively N is the element shape functions gq is the heat flow K is the thermal conductivity tensor
21
The boundary conditions for temperature flux convection and radiation are
)(
)(
)(
42
4112 TTF
n
T
TThn
T
qn
Tk
tzyxfT
w
sz
(235)
where T is the temperature k is the thermal conductivity n is the normal direction of the boundary szq
is the heat flux vector h is the convective
heat transfer coefficient wT is the surface temperature of the solid T is
the fluid temperature is the emissivity is the Stefan Boltzmann constant
223 FEM model for mechanical field
The equations that govern analyses of the behavior of a solid continuum are those of momentum conservation ie the equations of motion For an analysis of small deformation of a solid continuum these are (in tensor form) [17]
iijij ub (236)
where ij is the Cauchy stress tensor ib the body force vector per unit
volume the density and iu the displacement vector
To establish a weak form from the strong one we multiply (236) by an arbitrary velocity ie the test function iv and integrate over the region
By introducing two boundary conditions ii uu on u and ijijn on
where 0v on u the above differential equation in the weak form
[17] is given as
22
dvdbvduvdv iiiiiiijji (237)
To perform the FE discretization of the weak form (237) means to divide the continuum volume into sub-elements where the displacement field in every element is approximated by shape functions )(xNI and nodal
displacements )(tuiI that is summation of their products [17]
)()()( xNtutxu IiIi (238)
By approximating the test functions with the same shape functions (Galerkin method) we obtain
0)(
)()(
)(
)(
)(
)(
int)(
int
int
ee
e
e
dNbdNff
NdNMM
x
NBdBff
fuMfv
TTexte
ext
Te
j
IjI
Te
extT
(239)
which must hold for an arbitrary v and which puts the FE equation in order
intffuM ext (240)
For a linear material C the FE equation that emerges is
23
)(
)(e
dCBBKKfKuuM TTeext (241)
224 Numerical procedure
For the induction hardening process three different analyses have been combined in one numerical procedure mechanical thermal-metallurgical and electromagnetic (EM) computations They are solved fully transiently Boundary conditions and material properties beside one unique geometric model were required by each of them
What is necessary to mention is that some characteristics of the material are interdependent The electric conductivity for instance depends on the temperature In addition all thermal properties depend on the temperature [18] The variation of the properties with the temperature makes the system to be non-linear
There is a high coupling grade between thermal and EM equations because the electrical and magnetic properties laws depend on temperature When the initial temperature is known the eddy current value is calculated and then used to compute the heat generated by the Joule effect [5] At each time step the convergence is checked Until a steady state between the heat and the temperature field is reached the temperature value will be recalculated for each magnetic sub-step
EM solver can be coupled with the thermal and mechanical solvers in order to take full advantage of their capabilities [7] Both the thermal and the EM solver run with implicit time integration For mechanical solver there are two time integration methods of explicit and implicit type
Explicit and implicit methods are numerical schemes for obtaining numerical solutions of time-dependent ordinary and partial differential equations as is required in computer simulations of physical processes Explicit methods calculate the state of a system at a later time from the state of the system at the current time while implicit methods find a solution by solving an equation involving both the current state of the system and the later one [19] Here follows the difference between explicit and implicit methods
Implicit method
o More accurate
24
o It has large time step increment
o Convergence of each load step can be controlled to avoid error accumulation
o Iteration may not converge
Explicit method
o Less accurate
o It has small time step
o There is error accumulation and the error is difficult to estimate
o Iteration converges
However the implicit type has been governing the mechanical solver for the induction process in this thesis
Now let us go back to the couplings For the electromagnetic and structure interaction both the mechanical and the EM solver have distinct time steps By linear interpolation the EM fields are evaluated at the mechanical time step The two solvers will interact at each electromagnetic time step The EM solver will communicate the Lorentz force to the mechanical solver [7] resulting in an extra force in the mechanic equation
Lorentzext FfDt
Du (242)
where is total charge density is electrical conductivity extf is the
external force while LorentzF is the Lorentz force In turn the displacements
and deformations of the conductors are returned by the mechanical solver
When it comes to the thermal coupling at each electromagnetic time step the EM solver will communicate the extra Joule heating power term and the thermal solver will communicate the temperature
Figure 22 shows the interactions between the different solvers in LS-DYNA
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
3
Notation
A
Vector Potential [Tm]
a u Acceleration [ms2]
B
Magnetic flux density [T]
b Material coefficient [-]
C Specific Heat [Jkg K]
cC Capacitance [F]
pC Chemical composition []
c Empirical grain growth parameter [-]
dc Damping coefficient [N sm]
E Youngrsquos Modulus [Pa]
E
Electric field [Vm]
LorentzF Lorentz force [N]
f Frequency [kHz]
Df Damping force [N]
lf Inertial force [N]
Sf Elastic force [N]
G Energy release rate [Jm2]
gG Grain number [-]
H
Magnetic field intensity [Am]
Hv Hardness [-]
h Convection coefficient [W(m2K)]
I Current [A]
j
Current density [Am2]
sj
Source current density [Am2]
k Thermal conductivity [W(m K)]
4
sk Linear stiffness [Nm]
L Inductance [H]
m Mass [kg]
Ms temperature of the initial martensitic
transformation [K]
n Normal direction of the boundary [-]
p Phase proportion [-]
eqp Phase proportion calculated at thermodynamic equilibrium
[-]
Q Internal heat generation rate per unit volume [-]
kQ Activation energy [J]
q Charge [C]
szq
Heat flux vector [-]
R Resistance [Ω]
bR Radius [m]
uR Universal gas constant [J(mol K)]
r Position [m]
T Temperature [K]
wT Surface temperature of the solid [K]
T Fluid temperature [K]
t Time [sec]
u Displacement [m]
u v Velocity [ms]
V Voltage amplitude [V]
Vr Cooling rate at 700 [Ks]
kX Actual phase [-]
kx True amount of phase [-]
Material dependent constant [-]
Stress [Pa]
B Stefan Boltzmann constant [W(m2K4)]
5
C Electric conductivity [1(Ωm)]
Strain []
0 Permittivity of free space [Fm]
e Surface emissivity [-]
Scalar Potential [V]
Skin depth [m]
Magnetic Permeability [Hm]
0 Permeability of free space [Hm]
r Relative permeability [-]
Density [kgm3]
c Total Charge density [Cm3]
e Electrical resistivity [Ωm]
Shear stress [Pa]
R Delay time of the transformation [sec]
Poissons ratio [-]
Volume [m3]
Boundary surface of volume [m2]
Pulsation [rads]
6
1 Introduction
11 Background
The induction hardening is one of the methods for heat treatment of steel workpieces The induction hardening can be used for both through-hardening and to selectively harden areas of a part or assembly When the method is used to harden only the surface of the parts it has been applied to various machine parts such as automobile components and toothed gears [1]
The classic method of hardening contains first heating to an austenitic state (austenite has a Face Centre Cubic ndash FCC atomic structure) and then cooling rapidly Let us assume the initial phase being ferritic-pearlitic Ferrite has a Body Centre Cubic structure (BCC) which can hold very little carbon typically 00001 at room temperature It can exist as either alpha or delta ferrite Pearlite is a mixture of alternate strips of ferrite and cementite in a single grain The name for this structure is derived from pearl appearance seen under a microscope A fully pearlitic structure occurs at 08 Carbon
During heating see Figure 12 two processes occur Firstly the cementite starts to dissolve and the cementite particles to shrink When the temperature rises above a critical value the ferrite starts to transform to austenite Austenite formation and cementite dissolution occur faster the higher the temperature The structure is fully austenitic above the A3 (Ac3) or Accm line (the upper line in the Iron Carbon Diagram) Figure 11
7
Figure 11 Iron Carbon Diagram
Figure 12 Induction heating of a part
During cooling from the austenitic state several different phase transformations may take place depending on how fast the cooling process is When steel is cooled sufficiently rapidly other structures do not have sufficient time to form and the austenite can be retained at low temperatures since the diffusion-dependent transformations proceed slowly When the temperature is sufficiently low the tendency of austenite to be transformed becomes so strong that the transformation takes place without diffusion Such a transformation is called diffusionless and can in principle occur with two different mechanisms namely massive and martensitic transformation [2]
Figure 13 Quenching (cooling) of a part
8
In a martensitic transformation FCC structure of austenite rapidly changes to BCC leaving insufficient time for the carbon to form pearlite This results in a distorted structure that has the appearance of fine needles Only the parts of a section that cool fast enough will form martensite in a thick section it will only form to a certain depth and if the shape is complex it may only form in small pockets The hardness of martensite is solely dependant on carbon content it is normally very high unless the carbon content is exceptionally low The martensitic transformation is of great practical significance since it is the martensite which gives steel its high degree of hardness and strength
In the induction hardening of our interest the surface of the workpiece is heated up over the austenitization temperature by the induction heating Figure 12 and transformed from the ferritic and pearlitic structure Figure 14 A to the austenite structure Figure 14 B The heating process is then followed by immediate quenching process Figure 13 and the surface of the workpiece is transformed from the austenitic to the martensitic phase Figure 14 C and thereby hardened The heating condition for the induction hardening can be determined experimentally or empirically for the workpiece of any shape [1]
Figure 14 Specimen microstructures of normalized steel A) Ferritic-Pearlitic B) Austenitic and C) Martensitic
9
Induction heating is the process of heating an electrically conducting object by electromagnetic induction where eddy currents are generated within the metal and resistance leads to Joule heating of the metal [6] This process is widely used in industrial operations due to its high efficiency precise control and more environmentally friendly properties [3] The induction heating has some characteristics compared to the traditional heating methods (such as furnace heating)
It has a precise depth of heating and the heating zone which is easier to control
It is easy to implement high power density fast heating high efficiency and low energy consumption
It is easy to control the high heating temperature
The conduction and infiltration of the heating temperature will be from the surface to the interior
There are no penetrating impurities since non-contact heating method is used
The burned part on the workpiece is smaller
The process is somewhat eco-friendly
It is easy to accomplish the automation of heating process
The quenching part of an induction hardening process is also an important part Cooling rates must be rapid in order to avoid softer undesirable structures such as pearlite and bainite Due to its importance the cooling portion of the induction hardening process deserves careful consideration particularly when specifying new induction equipment and processes Process parameters must be precisely controlled to assure consistent heat treatment results Excessive variation in these parameters will cause undesirable or inconsistent process results including problems with case depth hardness pattern and distortion [4] Water quench has been used for the problem in this thesis
12 Aim
Let us go to the main objective of this work Although the induction hardening process has many advantages the design of it which is usually based on experiments can be tiresome time-consuming and expensive
10
Luckily the fast development of the computer technology makes it possible to model the induction heat treatment process with numerical tools particularly with Finite Element Method (FEM) Nowadays a lot of engineers pay attention to this area
There are many FEM modeling works regarding either the heating or quenching heat treatment in the literature However numerical models of the integrated heat treatment ie both the induction heating and quenching are still gaining ground [5] Induction hardening is a complex physical process which has contributions from electrical magnetic thermal mechanical and metallurgical processes It is obvious that the complexity of the phenomena ndash including phase transformation and heat exchange makes the FEM analysis heavy and difficult
Different FEM softwares have been used for numerical studies of the induction hardening process In this study LS-DYNA has been used for simulations The electromagnetic field the eddy current and the temperature field have been calculated with the FEM and Boundary Element Method (BEM) In fact FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air thus no air mesh is needed The main study included
The mathematical description and the modeling of the induction heat treatment process
Solving the induction-hardening-modeling key technical issues
Simulating the induction hardening process with the existing commercial software LS-DYNA
Comparing the results of the simulation with the literature values and evaluating the softwarersquos capability
In short the aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The simulation results have been compared to literature results for evaluation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Here follows the model selected from a literature source [5] the induction heating and cooling of cylindrical workpiece The experimental setup is made of three parts the coil the bar and the cooling tool Figure 15
11
Figure 15 The experimental set-up
12
2 Induction and the corresponding numerical background
21 Induction process - Maxwell equations
The basic model is shown in Figure 21
Figure 21 Induction heating principle
The partial differential equations are used to solve the electromagnetic field distribution
In order to define the equations solved by the electromagnetic solver in LS-DYNA we start with the Maxwell equations [7]
t
BE
(21)
t
EjH
0 (22)
0 B
(23)
13
0
E
(24)
sjEj
(25)
HB
0 (26)
where E
is electric field B
is magnetic flux density t is time H
is
magnetic field intensity j
is current density 0 is permittivity of free
space is total charge density is electric conductivity sj
is source
current density and 0 is permeability of free space
The eddy current approximation used here implies a divergence-free current
density and no charge accumulation thus resulting in 00
t
E
and 0
Equations (22) and (24) in the eddy current approximation give
jH
(27)
0 E
(28)
0 j
(29)
The divergence condition given by equation (23) allows writing B
as
AB
(210)
where A
is the magnetic vector potential [8] Equation (21) then implies that the electric field is given by
t
AE
(211)
14
where is the electric scalar potential
Equation (210) leaves a mathematical degree of freedom to A
(if A
is
transformed to a given
A then Equation (210) remains valid) Therefore the introduction of a gauge ie a particular choice of the scalar and vector potentials is needed Gauge choosing denotes a mathematical procedure for coping with redundant degrees of freedom in field variables The gauge chosen here is the generalized Coulomb gauge
0 A
(212)
Equations (25) (29) (211) and (212) give
0
(213)
Equations (25) (27) (211) and (210) give
sjAt
A
1
(214)
Equation (213) and Equation (214) are the two equations constituting the system that will be solved where A
and are the two unknowns of the
problem [7]
211 Skin effect and skin depth
Skin effect is the tendency of an alternating electric current (AC) to become distributed within a conductor such that the current density is largest near the surface of the conductor and decreases with greater depths in the conductor [9]
Skin effect is associated with the current flowing mainly at the skin of the conductor at an average depth called the skin depth The skin depth is
15
defined as the depth at which the electromagnetic field in a conducting material has decreased to 037 of its value just outside the material which describes the electric and magnetic fields The formula for the skin depth is given by
ff rr
503
)2(
22
0
(215)
where is the skin depth f is the frequency is the average electrical
resistivity and r is the average relative permeability
212 Proximity effect
A changing magnetic field will influence the distribution of an electric current flowing within an electrical conductor by electromagnetic induction When an alternating current flows through an isolated conductor it creates an associated alternating magnetic field around it The alternating magnetic field induces eddy currents in adjacent conductors altering the overall distribution of current flowing through them ndash the distribution of current within the conductor will be constrained to smaller regions Subsequently the resistance is increased in those regions The resulting current crowding is termed the proximity effect Usually the current is concentrated in the areas of the conductor furthest away from nearby conductors carrying current in the same direction [10]
Thus since in our case the inductor is a coil the maximum current density will be at the inner side of the coil [3] So the inner side of the coil will be used to heat the workpiece which will get faster temperature increase and will be more efficient
22 Numerical basis of the induction process
All the physical phenomena encountered in engineering mechanics are modeled by differential equations Usually it is difficult to obtain accurate analytical solution of the differential equation However the numerical solution could be calculated but only when boundary conditions and initial
16
conditions under specific situations were given The following numerical methods are used to model the induction process in LS-DYNA
Finite Element Method
The FEM is today a powerful (often the most powerful) tool for numerical solution of any differential equation whether this arises from structural mechanics fluid mechanics thermodynamics biology ecology or any other field of science [11]
The finite element method is a numerical approach by which general differential equations can be solved in an approximate manner [12] A domain of interest is represented as an assembly of finite elements The FEM is useful for problems with complicated geometries loadings and material properties where analytical solutions cannot be obtained [13]
The main steps in the general FE formulation and solution of a physical problem are [11]
o Establish the strong form of the governing differential equation
o Transform this differential equation into the weak form
o Choose trial functions for the unknown function that is choose element type(s) and mesh the solution domain
o Choose weight functions and establish the system of algebraic equations for each element (element equations)
o Assemble these element systems into the global system of algebraic equations
o Introduce boundary conditions into the global system of algebraic equations
o Solve the system of algebraic equations and present the results or use them for further calculations
Boundary Element Method
The boundary element method (BEM) is a numerical computational method of solving linear partial differential equations which have been formulated as integral equations BEM attempts to use the given boundary conditions to fit only boundary values into the integral equation Once this is done the integral equation can then be used again to calculate numerically solution at any desired point in the interior of the solution domain The boundary
17
element method is often more efficient than other methods including FEM in terms of computational resources for problems where there is a small surfacevolume ratio Conceptually it works by constructing a mesh over the modeled surface However for many problems boundary element methods are significantly less suitable and efficient than volume-discretization methods [14]
In numerical computations of the problem in this thesis with LS-DYNA FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air
221 FEM model for electromagnetic field
In LS-DYNA equation (213) is projected on the 0W forms (0-forms are continuous scalar basis functions that have a well defined gradient the gradient of a 0-form being a 1- form) and equation (214) is projected on
the 1W
forms (1-forms are vector basis functions with continuous tangential components but discontinuous normal components) They have a well defined curl the curl of a 1-form being a 2-form) giving after integrating by part the following weak formulations [15]
00 dW
(216)
dWAndW
dWAdWt
A
11
11
)(
1
(217)
where d an element of volume and the surface of with n
outer normal to
The and A
decompositions on respectfully 0W and 1W
give
0iiw (218)
1iiwaA
(219)
18
When replacing and A
in equation (216) and (217) by (218) and (219) one gets
0)(0 S (220)
SaDaSt
aM
)()
1()( 0111
(221)
where
the stiffness matrix of the 0-forms is given by
dWWjiS ji000 ))((
(222)
the mass matrix of the 1-forms is given by
dWWjiM ji111 ))((
(223)
the stiffness matrix of the 1-forms is given by
dWWjiS ji )()(1
))(1
( 111
(224)
the derivative matrix of the 0-1-forms is given by
dWWjiD ji )())(( 1001
(225)
the outside stiffness matrix is given by
19
dWWnjiS ji11)(
1))(
1(
(226)
where is the magnetic permeability n
is the normal vector is the volume and is the boundary surface of volume
Equation (220) and (221) form the FEM system with and a being the unknowns From this system only the outside stiffness matrix cannot be directly computed The calculation of this matrix will be made possible through the definition of the BEM system [7] The BEM system is used for the air and will not be shown in this report More information about it could be found in [7]
222 FEM model for temperature field
The steady state or transient temperature field on three dimensional geometries can also be solved by LS-DYNA Material properties may be temperature dependent and either isotopic or orthotropic A variety of time and temperature dependent boundary conditions can be specified including temperature flux convection and radiation The implementation of heat conduction into LS-DYNA is based on the work of Shapiro [16]
The differential equations of conduction of heat in a three-dimensional continuum is given by
Qkt
cijij
(227)
where )( txi is temperature )( ix is density )( ixcc is
the specific heat )( iijij xkk is thermal conductivity )( ixQQ is
internal heat generation rate per unit volume
The boundary conditions are
s on 1 (228)
20
ijij nk on 2 (229)
Initial conditions at 0t are given by
)(0 ix at 0tt (230)
where )(txx ii are coordinates as a function of time is prescribed
temperature on 1 and in is normal vector to 2
Equations (227-230) represent the strong form of a boundary value problem to be solved for the temperature field within the solid continuum [16]
The finite element method provides the following equations for the numerical solution of equations (227-230)
nnnnnnn HFHt
C
1 (231)
e
jie
eij
e
dcNNCC (232)
ejiji
T
e
eij
ee
dNNdNKNHH (233)
eigi
e
ei
ee
dNdqNFF (234)
where and are the parameters that are different when using different methods like Crank-Nicolson Galerkin and so on The parameter is taken to be in the interval [01] C H and F are the element stiffness load and boundary matrices respectively N is the element shape functions gq is the heat flow K is the thermal conductivity tensor
21
The boundary conditions for temperature flux convection and radiation are
)(
)(
)(
42
4112 TTF
n
T
TThn
T
qn
Tk
tzyxfT
w
sz
(235)
where T is the temperature k is the thermal conductivity n is the normal direction of the boundary szq
is the heat flux vector h is the convective
heat transfer coefficient wT is the surface temperature of the solid T is
the fluid temperature is the emissivity is the Stefan Boltzmann constant
223 FEM model for mechanical field
The equations that govern analyses of the behavior of a solid continuum are those of momentum conservation ie the equations of motion For an analysis of small deformation of a solid continuum these are (in tensor form) [17]
iijij ub (236)
where ij is the Cauchy stress tensor ib the body force vector per unit
volume the density and iu the displacement vector
To establish a weak form from the strong one we multiply (236) by an arbitrary velocity ie the test function iv and integrate over the region
By introducing two boundary conditions ii uu on u and ijijn on
where 0v on u the above differential equation in the weak form
[17] is given as
22
dvdbvduvdv iiiiiiijji (237)
To perform the FE discretization of the weak form (237) means to divide the continuum volume into sub-elements where the displacement field in every element is approximated by shape functions )(xNI and nodal
displacements )(tuiI that is summation of their products [17]
)()()( xNtutxu IiIi (238)
By approximating the test functions with the same shape functions (Galerkin method) we obtain
0)(
)()(
)(
)(
)(
)(
int)(
int
int
ee
e
e
dNbdNff
NdNMM
x
NBdBff
fuMfv
TTexte
ext
Te
j
IjI
Te
extT
(239)
which must hold for an arbitrary v and which puts the FE equation in order
intffuM ext (240)
For a linear material C the FE equation that emerges is
23
)(
)(e
dCBBKKfKuuM TTeext (241)
224 Numerical procedure
For the induction hardening process three different analyses have been combined in one numerical procedure mechanical thermal-metallurgical and electromagnetic (EM) computations They are solved fully transiently Boundary conditions and material properties beside one unique geometric model were required by each of them
What is necessary to mention is that some characteristics of the material are interdependent The electric conductivity for instance depends on the temperature In addition all thermal properties depend on the temperature [18] The variation of the properties with the temperature makes the system to be non-linear
There is a high coupling grade between thermal and EM equations because the electrical and magnetic properties laws depend on temperature When the initial temperature is known the eddy current value is calculated and then used to compute the heat generated by the Joule effect [5] At each time step the convergence is checked Until a steady state between the heat and the temperature field is reached the temperature value will be recalculated for each magnetic sub-step
EM solver can be coupled with the thermal and mechanical solvers in order to take full advantage of their capabilities [7] Both the thermal and the EM solver run with implicit time integration For mechanical solver there are two time integration methods of explicit and implicit type
Explicit and implicit methods are numerical schemes for obtaining numerical solutions of time-dependent ordinary and partial differential equations as is required in computer simulations of physical processes Explicit methods calculate the state of a system at a later time from the state of the system at the current time while implicit methods find a solution by solving an equation involving both the current state of the system and the later one [19] Here follows the difference between explicit and implicit methods
Implicit method
o More accurate
24
o It has large time step increment
o Convergence of each load step can be controlled to avoid error accumulation
o Iteration may not converge
Explicit method
o Less accurate
o It has small time step
o There is error accumulation and the error is difficult to estimate
o Iteration converges
However the implicit type has been governing the mechanical solver for the induction process in this thesis
Now let us go back to the couplings For the electromagnetic and structure interaction both the mechanical and the EM solver have distinct time steps By linear interpolation the EM fields are evaluated at the mechanical time step The two solvers will interact at each electromagnetic time step The EM solver will communicate the Lorentz force to the mechanical solver [7] resulting in an extra force in the mechanic equation
Lorentzext FfDt
Du (242)
where is total charge density is electrical conductivity extf is the
external force while LorentzF is the Lorentz force In turn the displacements
and deformations of the conductors are returned by the mechanical solver
When it comes to the thermal coupling at each electromagnetic time step the EM solver will communicate the extra Joule heating power term and the thermal solver will communicate the temperature
Figure 22 shows the interactions between the different solvers in LS-DYNA
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
4
sk Linear stiffness [Nm]
L Inductance [H]
m Mass [kg]
Ms temperature of the initial martensitic
transformation [K]
n Normal direction of the boundary [-]
p Phase proportion [-]
eqp Phase proportion calculated at thermodynamic equilibrium
[-]
Q Internal heat generation rate per unit volume [-]
kQ Activation energy [J]
q Charge [C]
szq
Heat flux vector [-]
R Resistance [Ω]
bR Radius [m]
uR Universal gas constant [J(mol K)]
r Position [m]
T Temperature [K]
wT Surface temperature of the solid [K]
T Fluid temperature [K]
t Time [sec]
u Displacement [m]
u v Velocity [ms]
V Voltage amplitude [V]
Vr Cooling rate at 700 [Ks]
kX Actual phase [-]
kx True amount of phase [-]
Material dependent constant [-]
Stress [Pa]
B Stefan Boltzmann constant [W(m2K4)]
5
C Electric conductivity [1(Ωm)]
Strain []
0 Permittivity of free space [Fm]
e Surface emissivity [-]
Scalar Potential [V]
Skin depth [m]
Magnetic Permeability [Hm]
0 Permeability of free space [Hm]
r Relative permeability [-]
Density [kgm3]
c Total Charge density [Cm3]
e Electrical resistivity [Ωm]
Shear stress [Pa]
R Delay time of the transformation [sec]
Poissons ratio [-]
Volume [m3]
Boundary surface of volume [m2]
Pulsation [rads]
6
1 Introduction
11 Background
The induction hardening is one of the methods for heat treatment of steel workpieces The induction hardening can be used for both through-hardening and to selectively harden areas of a part or assembly When the method is used to harden only the surface of the parts it has been applied to various machine parts such as automobile components and toothed gears [1]
The classic method of hardening contains first heating to an austenitic state (austenite has a Face Centre Cubic ndash FCC atomic structure) and then cooling rapidly Let us assume the initial phase being ferritic-pearlitic Ferrite has a Body Centre Cubic structure (BCC) which can hold very little carbon typically 00001 at room temperature It can exist as either alpha or delta ferrite Pearlite is a mixture of alternate strips of ferrite and cementite in a single grain The name for this structure is derived from pearl appearance seen under a microscope A fully pearlitic structure occurs at 08 Carbon
During heating see Figure 12 two processes occur Firstly the cementite starts to dissolve and the cementite particles to shrink When the temperature rises above a critical value the ferrite starts to transform to austenite Austenite formation and cementite dissolution occur faster the higher the temperature The structure is fully austenitic above the A3 (Ac3) or Accm line (the upper line in the Iron Carbon Diagram) Figure 11
7
Figure 11 Iron Carbon Diagram
Figure 12 Induction heating of a part
During cooling from the austenitic state several different phase transformations may take place depending on how fast the cooling process is When steel is cooled sufficiently rapidly other structures do not have sufficient time to form and the austenite can be retained at low temperatures since the diffusion-dependent transformations proceed slowly When the temperature is sufficiently low the tendency of austenite to be transformed becomes so strong that the transformation takes place without diffusion Such a transformation is called diffusionless and can in principle occur with two different mechanisms namely massive and martensitic transformation [2]
Figure 13 Quenching (cooling) of a part
8
In a martensitic transformation FCC structure of austenite rapidly changes to BCC leaving insufficient time for the carbon to form pearlite This results in a distorted structure that has the appearance of fine needles Only the parts of a section that cool fast enough will form martensite in a thick section it will only form to a certain depth and if the shape is complex it may only form in small pockets The hardness of martensite is solely dependant on carbon content it is normally very high unless the carbon content is exceptionally low The martensitic transformation is of great practical significance since it is the martensite which gives steel its high degree of hardness and strength
In the induction hardening of our interest the surface of the workpiece is heated up over the austenitization temperature by the induction heating Figure 12 and transformed from the ferritic and pearlitic structure Figure 14 A to the austenite structure Figure 14 B The heating process is then followed by immediate quenching process Figure 13 and the surface of the workpiece is transformed from the austenitic to the martensitic phase Figure 14 C and thereby hardened The heating condition for the induction hardening can be determined experimentally or empirically for the workpiece of any shape [1]
Figure 14 Specimen microstructures of normalized steel A) Ferritic-Pearlitic B) Austenitic and C) Martensitic
9
Induction heating is the process of heating an electrically conducting object by electromagnetic induction where eddy currents are generated within the metal and resistance leads to Joule heating of the metal [6] This process is widely used in industrial operations due to its high efficiency precise control and more environmentally friendly properties [3] The induction heating has some characteristics compared to the traditional heating methods (such as furnace heating)
It has a precise depth of heating and the heating zone which is easier to control
It is easy to implement high power density fast heating high efficiency and low energy consumption
It is easy to control the high heating temperature
The conduction and infiltration of the heating temperature will be from the surface to the interior
There are no penetrating impurities since non-contact heating method is used
The burned part on the workpiece is smaller
The process is somewhat eco-friendly
It is easy to accomplish the automation of heating process
The quenching part of an induction hardening process is also an important part Cooling rates must be rapid in order to avoid softer undesirable structures such as pearlite and bainite Due to its importance the cooling portion of the induction hardening process deserves careful consideration particularly when specifying new induction equipment and processes Process parameters must be precisely controlled to assure consistent heat treatment results Excessive variation in these parameters will cause undesirable or inconsistent process results including problems with case depth hardness pattern and distortion [4] Water quench has been used for the problem in this thesis
12 Aim
Let us go to the main objective of this work Although the induction hardening process has many advantages the design of it which is usually based on experiments can be tiresome time-consuming and expensive
10
Luckily the fast development of the computer technology makes it possible to model the induction heat treatment process with numerical tools particularly with Finite Element Method (FEM) Nowadays a lot of engineers pay attention to this area
There are many FEM modeling works regarding either the heating or quenching heat treatment in the literature However numerical models of the integrated heat treatment ie both the induction heating and quenching are still gaining ground [5] Induction hardening is a complex physical process which has contributions from electrical magnetic thermal mechanical and metallurgical processes It is obvious that the complexity of the phenomena ndash including phase transformation and heat exchange makes the FEM analysis heavy and difficult
Different FEM softwares have been used for numerical studies of the induction hardening process In this study LS-DYNA has been used for simulations The electromagnetic field the eddy current and the temperature field have been calculated with the FEM and Boundary Element Method (BEM) In fact FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air thus no air mesh is needed The main study included
The mathematical description and the modeling of the induction heat treatment process
Solving the induction-hardening-modeling key technical issues
Simulating the induction hardening process with the existing commercial software LS-DYNA
Comparing the results of the simulation with the literature values and evaluating the softwarersquos capability
In short the aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The simulation results have been compared to literature results for evaluation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Here follows the model selected from a literature source [5] the induction heating and cooling of cylindrical workpiece The experimental setup is made of three parts the coil the bar and the cooling tool Figure 15
11
Figure 15 The experimental set-up
12
2 Induction and the corresponding numerical background
21 Induction process - Maxwell equations
The basic model is shown in Figure 21
Figure 21 Induction heating principle
The partial differential equations are used to solve the electromagnetic field distribution
In order to define the equations solved by the electromagnetic solver in LS-DYNA we start with the Maxwell equations [7]
t
BE
(21)
t
EjH
0 (22)
0 B
(23)
13
0
E
(24)
sjEj
(25)
HB
0 (26)
where E
is electric field B
is magnetic flux density t is time H
is
magnetic field intensity j
is current density 0 is permittivity of free
space is total charge density is electric conductivity sj
is source
current density and 0 is permeability of free space
The eddy current approximation used here implies a divergence-free current
density and no charge accumulation thus resulting in 00
t
E
and 0
Equations (22) and (24) in the eddy current approximation give
jH
(27)
0 E
(28)
0 j
(29)
The divergence condition given by equation (23) allows writing B
as
AB
(210)
where A
is the magnetic vector potential [8] Equation (21) then implies that the electric field is given by
t
AE
(211)
14
where is the electric scalar potential
Equation (210) leaves a mathematical degree of freedom to A
(if A
is
transformed to a given
A then Equation (210) remains valid) Therefore the introduction of a gauge ie a particular choice of the scalar and vector potentials is needed Gauge choosing denotes a mathematical procedure for coping with redundant degrees of freedom in field variables The gauge chosen here is the generalized Coulomb gauge
0 A
(212)
Equations (25) (29) (211) and (212) give
0
(213)
Equations (25) (27) (211) and (210) give
sjAt
A
1
(214)
Equation (213) and Equation (214) are the two equations constituting the system that will be solved where A
and are the two unknowns of the
problem [7]
211 Skin effect and skin depth
Skin effect is the tendency of an alternating electric current (AC) to become distributed within a conductor such that the current density is largest near the surface of the conductor and decreases with greater depths in the conductor [9]
Skin effect is associated with the current flowing mainly at the skin of the conductor at an average depth called the skin depth The skin depth is
15
defined as the depth at which the electromagnetic field in a conducting material has decreased to 037 of its value just outside the material which describes the electric and magnetic fields The formula for the skin depth is given by
ff rr
503
)2(
22
0
(215)
where is the skin depth f is the frequency is the average electrical
resistivity and r is the average relative permeability
212 Proximity effect
A changing magnetic field will influence the distribution of an electric current flowing within an electrical conductor by electromagnetic induction When an alternating current flows through an isolated conductor it creates an associated alternating magnetic field around it The alternating magnetic field induces eddy currents in adjacent conductors altering the overall distribution of current flowing through them ndash the distribution of current within the conductor will be constrained to smaller regions Subsequently the resistance is increased in those regions The resulting current crowding is termed the proximity effect Usually the current is concentrated in the areas of the conductor furthest away from nearby conductors carrying current in the same direction [10]
Thus since in our case the inductor is a coil the maximum current density will be at the inner side of the coil [3] So the inner side of the coil will be used to heat the workpiece which will get faster temperature increase and will be more efficient
22 Numerical basis of the induction process
All the physical phenomena encountered in engineering mechanics are modeled by differential equations Usually it is difficult to obtain accurate analytical solution of the differential equation However the numerical solution could be calculated but only when boundary conditions and initial
16
conditions under specific situations were given The following numerical methods are used to model the induction process in LS-DYNA
Finite Element Method
The FEM is today a powerful (often the most powerful) tool for numerical solution of any differential equation whether this arises from structural mechanics fluid mechanics thermodynamics biology ecology or any other field of science [11]
The finite element method is a numerical approach by which general differential equations can be solved in an approximate manner [12] A domain of interest is represented as an assembly of finite elements The FEM is useful for problems with complicated geometries loadings and material properties where analytical solutions cannot be obtained [13]
The main steps in the general FE formulation and solution of a physical problem are [11]
o Establish the strong form of the governing differential equation
o Transform this differential equation into the weak form
o Choose trial functions for the unknown function that is choose element type(s) and mesh the solution domain
o Choose weight functions and establish the system of algebraic equations for each element (element equations)
o Assemble these element systems into the global system of algebraic equations
o Introduce boundary conditions into the global system of algebraic equations
o Solve the system of algebraic equations and present the results or use them for further calculations
Boundary Element Method
The boundary element method (BEM) is a numerical computational method of solving linear partial differential equations which have been formulated as integral equations BEM attempts to use the given boundary conditions to fit only boundary values into the integral equation Once this is done the integral equation can then be used again to calculate numerically solution at any desired point in the interior of the solution domain The boundary
17
element method is often more efficient than other methods including FEM in terms of computational resources for problems where there is a small surfacevolume ratio Conceptually it works by constructing a mesh over the modeled surface However for many problems boundary element methods are significantly less suitable and efficient than volume-discretization methods [14]
In numerical computations of the problem in this thesis with LS-DYNA FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air
221 FEM model for electromagnetic field
In LS-DYNA equation (213) is projected on the 0W forms (0-forms are continuous scalar basis functions that have a well defined gradient the gradient of a 0-form being a 1- form) and equation (214) is projected on
the 1W
forms (1-forms are vector basis functions with continuous tangential components but discontinuous normal components) They have a well defined curl the curl of a 1-form being a 2-form) giving after integrating by part the following weak formulations [15]
00 dW
(216)
dWAndW
dWAdWt
A
11
11
)(
1
(217)
where d an element of volume and the surface of with n
outer normal to
The and A
decompositions on respectfully 0W and 1W
give
0iiw (218)
1iiwaA
(219)
18
When replacing and A
in equation (216) and (217) by (218) and (219) one gets
0)(0 S (220)
SaDaSt
aM
)()
1()( 0111
(221)
where
the stiffness matrix of the 0-forms is given by
dWWjiS ji000 ))((
(222)
the mass matrix of the 1-forms is given by
dWWjiM ji111 ))((
(223)
the stiffness matrix of the 1-forms is given by
dWWjiS ji )()(1
))(1
( 111
(224)
the derivative matrix of the 0-1-forms is given by
dWWjiD ji )())(( 1001
(225)
the outside stiffness matrix is given by
19
dWWnjiS ji11)(
1))(
1(
(226)
where is the magnetic permeability n
is the normal vector is the volume and is the boundary surface of volume
Equation (220) and (221) form the FEM system with and a being the unknowns From this system only the outside stiffness matrix cannot be directly computed The calculation of this matrix will be made possible through the definition of the BEM system [7] The BEM system is used for the air and will not be shown in this report More information about it could be found in [7]
222 FEM model for temperature field
The steady state or transient temperature field on three dimensional geometries can also be solved by LS-DYNA Material properties may be temperature dependent and either isotopic or orthotropic A variety of time and temperature dependent boundary conditions can be specified including temperature flux convection and radiation The implementation of heat conduction into LS-DYNA is based on the work of Shapiro [16]
The differential equations of conduction of heat in a three-dimensional continuum is given by
Qkt
cijij
(227)
where )( txi is temperature )( ix is density )( ixcc is
the specific heat )( iijij xkk is thermal conductivity )( ixQQ is
internal heat generation rate per unit volume
The boundary conditions are
s on 1 (228)
20
ijij nk on 2 (229)
Initial conditions at 0t are given by
)(0 ix at 0tt (230)
where )(txx ii are coordinates as a function of time is prescribed
temperature on 1 and in is normal vector to 2
Equations (227-230) represent the strong form of a boundary value problem to be solved for the temperature field within the solid continuum [16]
The finite element method provides the following equations for the numerical solution of equations (227-230)
nnnnnnn HFHt
C
1 (231)
e
jie
eij
e
dcNNCC (232)
ejiji
T
e
eij
ee
dNNdNKNHH (233)
eigi
e
ei
ee
dNdqNFF (234)
where and are the parameters that are different when using different methods like Crank-Nicolson Galerkin and so on The parameter is taken to be in the interval [01] C H and F are the element stiffness load and boundary matrices respectively N is the element shape functions gq is the heat flow K is the thermal conductivity tensor
21
The boundary conditions for temperature flux convection and radiation are
)(
)(
)(
42
4112 TTF
n
T
TThn
T
qn
Tk
tzyxfT
w
sz
(235)
where T is the temperature k is the thermal conductivity n is the normal direction of the boundary szq
is the heat flux vector h is the convective
heat transfer coefficient wT is the surface temperature of the solid T is
the fluid temperature is the emissivity is the Stefan Boltzmann constant
223 FEM model for mechanical field
The equations that govern analyses of the behavior of a solid continuum are those of momentum conservation ie the equations of motion For an analysis of small deformation of a solid continuum these are (in tensor form) [17]
iijij ub (236)
where ij is the Cauchy stress tensor ib the body force vector per unit
volume the density and iu the displacement vector
To establish a weak form from the strong one we multiply (236) by an arbitrary velocity ie the test function iv and integrate over the region
By introducing two boundary conditions ii uu on u and ijijn on
where 0v on u the above differential equation in the weak form
[17] is given as
22
dvdbvduvdv iiiiiiijji (237)
To perform the FE discretization of the weak form (237) means to divide the continuum volume into sub-elements where the displacement field in every element is approximated by shape functions )(xNI and nodal
displacements )(tuiI that is summation of their products [17]
)()()( xNtutxu IiIi (238)
By approximating the test functions with the same shape functions (Galerkin method) we obtain
0)(
)()(
)(
)(
)(
)(
int)(
int
int
ee
e
e
dNbdNff
NdNMM
x
NBdBff
fuMfv
TTexte
ext
Te
j
IjI
Te
extT
(239)
which must hold for an arbitrary v and which puts the FE equation in order
intffuM ext (240)
For a linear material C the FE equation that emerges is
23
)(
)(e
dCBBKKfKuuM TTeext (241)
224 Numerical procedure
For the induction hardening process three different analyses have been combined in one numerical procedure mechanical thermal-metallurgical and electromagnetic (EM) computations They are solved fully transiently Boundary conditions and material properties beside one unique geometric model were required by each of them
What is necessary to mention is that some characteristics of the material are interdependent The electric conductivity for instance depends on the temperature In addition all thermal properties depend on the temperature [18] The variation of the properties with the temperature makes the system to be non-linear
There is a high coupling grade between thermal and EM equations because the electrical and magnetic properties laws depend on temperature When the initial temperature is known the eddy current value is calculated and then used to compute the heat generated by the Joule effect [5] At each time step the convergence is checked Until a steady state between the heat and the temperature field is reached the temperature value will be recalculated for each magnetic sub-step
EM solver can be coupled with the thermal and mechanical solvers in order to take full advantage of their capabilities [7] Both the thermal and the EM solver run with implicit time integration For mechanical solver there are two time integration methods of explicit and implicit type
Explicit and implicit methods are numerical schemes for obtaining numerical solutions of time-dependent ordinary and partial differential equations as is required in computer simulations of physical processes Explicit methods calculate the state of a system at a later time from the state of the system at the current time while implicit methods find a solution by solving an equation involving both the current state of the system and the later one [19] Here follows the difference between explicit and implicit methods
Implicit method
o More accurate
24
o It has large time step increment
o Convergence of each load step can be controlled to avoid error accumulation
o Iteration may not converge
Explicit method
o Less accurate
o It has small time step
o There is error accumulation and the error is difficult to estimate
o Iteration converges
However the implicit type has been governing the mechanical solver for the induction process in this thesis
Now let us go back to the couplings For the electromagnetic and structure interaction both the mechanical and the EM solver have distinct time steps By linear interpolation the EM fields are evaluated at the mechanical time step The two solvers will interact at each electromagnetic time step The EM solver will communicate the Lorentz force to the mechanical solver [7] resulting in an extra force in the mechanic equation
Lorentzext FfDt
Du (242)
where is total charge density is electrical conductivity extf is the
external force while LorentzF is the Lorentz force In turn the displacements
and deformations of the conductors are returned by the mechanical solver
When it comes to the thermal coupling at each electromagnetic time step the EM solver will communicate the extra Joule heating power term and the thermal solver will communicate the temperature
Figure 22 shows the interactions between the different solvers in LS-DYNA
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
5
C Electric conductivity [1(Ωm)]
Strain []
0 Permittivity of free space [Fm]
e Surface emissivity [-]
Scalar Potential [V]
Skin depth [m]
Magnetic Permeability [Hm]
0 Permeability of free space [Hm]
r Relative permeability [-]
Density [kgm3]
c Total Charge density [Cm3]
e Electrical resistivity [Ωm]
Shear stress [Pa]
R Delay time of the transformation [sec]
Poissons ratio [-]
Volume [m3]
Boundary surface of volume [m2]
Pulsation [rads]
6
1 Introduction
11 Background
The induction hardening is one of the methods for heat treatment of steel workpieces The induction hardening can be used for both through-hardening and to selectively harden areas of a part or assembly When the method is used to harden only the surface of the parts it has been applied to various machine parts such as automobile components and toothed gears [1]
The classic method of hardening contains first heating to an austenitic state (austenite has a Face Centre Cubic ndash FCC atomic structure) and then cooling rapidly Let us assume the initial phase being ferritic-pearlitic Ferrite has a Body Centre Cubic structure (BCC) which can hold very little carbon typically 00001 at room temperature It can exist as either alpha or delta ferrite Pearlite is a mixture of alternate strips of ferrite and cementite in a single grain The name for this structure is derived from pearl appearance seen under a microscope A fully pearlitic structure occurs at 08 Carbon
During heating see Figure 12 two processes occur Firstly the cementite starts to dissolve and the cementite particles to shrink When the temperature rises above a critical value the ferrite starts to transform to austenite Austenite formation and cementite dissolution occur faster the higher the temperature The structure is fully austenitic above the A3 (Ac3) or Accm line (the upper line in the Iron Carbon Diagram) Figure 11
7
Figure 11 Iron Carbon Diagram
Figure 12 Induction heating of a part
During cooling from the austenitic state several different phase transformations may take place depending on how fast the cooling process is When steel is cooled sufficiently rapidly other structures do not have sufficient time to form and the austenite can be retained at low temperatures since the diffusion-dependent transformations proceed slowly When the temperature is sufficiently low the tendency of austenite to be transformed becomes so strong that the transformation takes place without diffusion Such a transformation is called diffusionless and can in principle occur with two different mechanisms namely massive and martensitic transformation [2]
Figure 13 Quenching (cooling) of a part
8
In a martensitic transformation FCC structure of austenite rapidly changes to BCC leaving insufficient time for the carbon to form pearlite This results in a distorted structure that has the appearance of fine needles Only the parts of a section that cool fast enough will form martensite in a thick section it will only form to a certain depth and if the shape is complex it may only form in small pockets The hardness of martensite is solely dependant on carbon content it is normally very high unless the carbon content is exceptionally low The martensitic transformation is of great practical significance since it is the martensite which gives steel its high degree of hardness and strength
In the induction hardening of our interest the surface of the workpiece is heated up over the austenitization temperature by the induction heating Figure 12 and transformed from the ferritic and pearlitic structure Figure 14 A to the austenite structure Figure 14 B The heating process is then followed by immediate quenching process Figure 13 and the surface of the workpiece is transformed from the austenitic to the martensitic phase Figure 14 C and thereby hardened The heating condition for the induction hardening can be determined experimentally or empirically for the workpiece of any shape [1]
Figure 14 Specimen microstructures of normalized steel A) Ferritic-Pearlitic B) Austenitic and C) Martensitic
9
Induction heating is the process of heating an electrically conducting object by electromagnetic induction where eddy currents are generated within the metal and resistance leads to Joule heating of the metal [6] This process is widely used in industrial operations due to its high efficiency precise control and more environmentally friendly properties [3] The induction heating has some characteristics compared to the traditional heating methods (such as furnace heating)
It has a precise depth of heating and the heating zone which is easier to control
It is easy to implement high power density fast heating high efficiency and low energy consumption
It is easy to control the high heating temperature
The conduction and infiltration of the heating temperature will be from the surface to the interior
There are no penetrating impurities since non-contact heating method is used
The burned part on the workpiece is smaller
The process is somewhat eco-friendly
It is easy to accomplish the automation of heating process
The quenching part of an induction hardening process is also an important part Cooling rates must be rapid in order to avoid softer undesirable structures such as pearlite and bainite Due to its importance the cooling portion of the induction hardening process deserves careful consideration particularly when specifying new induction equipment and processes Process parameters must be precisely controlled to assure consistent heat treatment results Excessive variation in these parameters will cause undesirable or inconsistent process results including problems with case depth hardness pattern and distortion [4] Water quench has been used for the problem in this thesis
12 Aim
Let us go to the main objective of this work Although the induction hardening process has many advantages the design of it which is usually based on experiments can be tiresome time-consuming and expensive
10
Luckily the fast development of the computer technology makes it possible to model the induction heat treatment process with numerical tools particularly with Finite Element Method (FEM) Nowadays a lot of engineers pay attention to this area
There are many FEM modeling works regarding either the heating or quenching heat treatment in the literature However numerical models of the integrated heat treatment ie both the induction heating and quenching are still gaining ground [5] Induction hardening is a complex physical process which has contributions from electrical magnetic thermal mechanical and metallurgical processes It is obvious that the complexity of the phenomena ndash including phase transformation and heat exchange makes the FEM analysis heavy and difficult
Different FEM softwares have been used for numerical studies of the induction hardening process In this study LS-DYNA has been used for simulations The electromagnetic field the eddy current and the temperature field have been calculated with the FEM and Boundary Element Method (BEM) In fact FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air thus no air mesh is needed The main study included
The mathematical description and the modeling of the induction heat treatment process
Solving the induction-hardening-modeling key technical issues
Simulating the induction hardening process with the existing commercial software LS-DYNA
Comparing the results of the simulation with the literature values and evaluating the softwarersquos capability
In short the aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The simulation results have been compared to literature results for evaluation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Here follows the model selected from a literature source [5] the induction heating and cooling of cylindrical workpiece The experimental setup is made of three parts the coil the bar and the cooling tool Figure 15
11
Figure 15 The experimental set-up
12
2 Induction and the corresponding numerical background
21 Induction process - Maxwell equations
The basic model is shown in Figure 21
Figure 21 Induction heating principle
The partial differential equations are used to solve the electromagnetic field distribution
In order to define the equations solved by the electromagnetic solver in LS-DYNA we start with the Maxwell equations [7]
t
BE
(21)
t
EjH
0 (22)
0 B
(23)
13
0
E
(24)
sjEj
(25)
HB
0 (26)
where E
is electric field B
is magnetic flux density t is time H
is
magnetic field intensity j
is current density 0 is permittivity of free
space is total charge density is electric conductivity sj
is source
current density and 0 is permeability of free space
The eddy current approximation used here implies a divergence-free current
density and no charge accumulation thus resulting in 00
t
E
and 0
Equations (22) and (24) in the eddy current approximation give
jH
(27)
0 E
(28)
0 j
(29)
The divergence condition given by equation (23) allows writing B
as
AB
(210)
where A
is the magnetic vector potential [8] Equation (21) then implies that the electric field is given by
t
AE
(211)
14
where is the electric scalar potential
Equation (210) leaves a mathematical degree of freedom to A
(if A
is
transformed to a given
A then Equation (210) remains valid) Therefore the introduction of a gauge ie a particular choice of the scalar and vector potentials is needed Gauge choosing denotes a mathematical procedure for coping with redundant degrees of freedom in field variables The gauge chosen here is the generalized Coulomb gauge
0 A
(212)
Equations (25) (29) (211) and (212) give
0
(213)
Equations (25) (27) (211) and (210) give
sjAt
A
1
(214)
Equation (213) and Equation (214) are the two equations constituting the system that will be solved where A
and are the two unknowns of the
problem [7]
211 Skin effect and skin depth
Skin effect is the tendency of an alternating electric current (AC) to become distributed within a conductor such that the current density is largest near the surface of the conductor and decreases with greater depths in the conductor [9]
Skin effect is associated with the current flowing mainly at the skin of the conductor at an average depth called the skin depth The skin depth is
15
defined as the depth at which the electromagnetic field in a conducting material has decreased to 037 of its value just outside the material which describes the electric and magnetic fields The formula for the skin depth is given by
ff rr
503
)2(
22
0
(215)
where is the skin depth f is the frequency is the average electrical
resistivity and r is the average relative permeability
212 Proximity effect
A changing magnetic field will influence the distribution of an electric current flowing within an electrical conductor by electromagnetic induction When an alternating current flows through an isolated conductor it creates an associated alternating magnetic field around it The alternating magnetic field induces eddy currents in adjacent conductors altering the overall distribution of current flowing through them ndash the distribution of current within the conductor will be constrained to smaller regions Subsequently the resistance is increased in those regions The resulting current crowding is termed the proximity effect Usually the current is concentrated in the areas of the conductor furthest away from nearby conductors carrying current in the same direction [10]
Thus since in our case the inductor is a coil the maximum current density will be at the inner side of the coil [3] So the inner side of the coil will be used to heat the workpiece which will get faster temperature increase and will be more efficient
22 Numerical basis of the induction process
All the physical phenomena encountered in engineering mechanics are modeled by differential equations Usually it is difficult to obtain accurate analytical solution of the differential equation However the numerical solution could be calculated but only when boundary conditions and initial
16
conditions under specific situations were given The following numerical methods are used to model the induction process in LS-DYNA
Finite Element Method
The FEM is today a powerful (often the most powerful) tool for numerical solution of any differential equation whether this arises from structural mechanics fluid mechanics thermodynamics biology ecology or any other field of science [11]
The finite element method is a numerical approach by which general differential equations can be solved in an approximate manner [12] A domain of interest is represented as an assembly of finite elements The FEM is useful for problems with complicated geometries loadings and material properties where analytical solutions cannot be obtained [13]
The main steps in the general FE formulation and solution of a physical problem are [11]
o Establish the strong form of the governing differential equation
o Transform this differential equation into the weak form
o Choose trial functions for the unknown function that is choose element type(s) and mesh the solution domain
o Choose weight functions and establish the system of algebraic equations for each element (element equations)
o Assemble these element systems into the global system of algebraic equations
o Introduce boundary conditions into the global system of algebraic equations
o Solve the system of algebraic equations and present the results or use them for further calculations
Boundary Element Method
The boundary element method (BEM) is a numerical computational method of solving linear partial differential equations which have been formulated as integral equations BEM attempts to use the given boundary conditions to fit only boundary values into the integral equation Once this is done the integral equation can then be used again to calculate numerically solution at any desired point in the interior of the solution domain The boundary
17
element method is often more efficient than other methods including FEM in terms of computational resources for problems where there is a small surfacevolume ratio Conceptually it works by constructing a mesh over the modeled surface However for many problems boundary element methods are significantly less suitable and efficient than volume-discretization methods [14]
In numerical computations of the problem in this thesis with LS-DYNA FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air
221 FEM model for electromagnetic field
In LS-DYNA equation (213) is projected on the 0W forms (0-forms are continuous scalar basis functions that have a well defined gradient the gradient of a 0-form being a 1- form) and equation (214) is projected on
the 1W
forms (1-forms are vector basis functions with continuous tangential components but discontinuous normal components) They have a well defined curl the curl of a 1-form being a 2-form) giving after integrating by part the following weak formulations [15]
00 dW
(216)
dWAndW
dWAdWt
A
11
11
)(
1
(217)
where d an element of volume and the surface of with n
outer normal to
The and A
decompositions on respectfully 0W and 1W
give
0iiw (218)
1iiwaA
(219)
18
When replacing and A
in equation (216) and (217) by (218) and (219) one gets
0)(0 S (220)
SaDaSt
aM
)()
1()( 0111
(221)
where
the stiffness matrix of the 0-forms is given by
dWWjiS ji000 ))((
(222)
the mass matrix of the 1-forms is given by
dWWjiM ji111 ))((
(223)
the stiffness matrix of the 1-forms is given by
dWWjiS ji )()(1
))(1
( 111
(224)
the derivative matrix of the 0-1-forms is given by
dWWjiD ji )())(( 1001
(225)
the outside stiffness matrix is given by
19
dWWnjiS ji11)(
1))(
1(
(226)
where is the magnetic permeability n
is the normal vector is the volume and is the boundary surface of volume
Equation (220) and (221) form the FEM system with and a being the unknowns From this system only the outside stiffness matrix cannot be directly computed The calculation of this matrix will be made possible through the definition of the BEM system [7] The BEM system is used for the air and will not be shown in this report More information about it could be found in [7]
222 FEM model for temperature field
The steady state or transient temperature field on three dimensional geometries can also be solved by LS-DYNA Material properties may be temperature dependent and either isotopic or orthotropic A variety of time and temperature dependent boundary conditions can be specified including temperature flux convection and radiation The implementation of heat conduction into LS-DYNA is based on the work of Shapiro [16]
The differential equations of conduction of heat in a three-dimensional continuum is given by
Qkt
cijij
(227)
where )( txi is temperature )( ix is density )( ixcc is
the specific heat )( iijij xkk is thermal conductivity )( ixQQ is
internal heat generation rate per unit volume
The boundary conditions are
s on 1 (228)
20
ijij nk on 2 (229)
Initial conditions at 0t are given by
)(0 ix at 0tt (230)
where )(txx ii are coordinates as a function of time is prescribed
temperature on 1 and in is normal vector to 2
Equations (227-230) represent the strong form of a boundary value problem to be solved for the temperature field within the solid continuum [16]
The finite element method provides the following equations for the numerical solution of equations (227-230)
nnnnnnn HFHt
C
1 (231)
e
jie
eij
e
dcNNCC (232)
ejiji
T
e
eij
ee
dNNdNKNHH (233)
eigi
e
ei
ee
dNdqNFF (234)
where and are the parameters that are different when using different methods like Crank-Nicolson Galerkin and so on The parameter is taken to be in the interval [01] C H and F are the element stiffness load and boundary matrices respectively N is the element shape functions gq is the heat flow K is the thermal conductivity tensor
21
The boundary conditions for temperature flux convection and radiation are
)(
)(
)(
42
4112 TTF
n
T
TThn
T
qn
Tk
tzyxfT
w
sz
(235)
where T is the temperature k is the thermal conductivity n is the normal direction of the boundary szq
is the heat flux vector h is the convective
heat transfer coefficient wT is the surface temperature of the solid T is
the fluid temperature is the emissivity is the Stefan Boltzmann constant
223 FEM model for mechanical field
The equations that govern analyses of the behavior of a solid continuum are those of momentum conservation ie the equations of motion For an analysis of small deformation of a solid continuum these are (in tensor form) [17]
iijij ub (236)
where ij is the Cauchy stress tensor ib the body force vector per unit
volume the density and iu the displacement vector
To establish a weak form from the strong one we multiply (236) by an arbitrary velocity ie the test function iv and integrate over the region
By introducing two boundary conditions ii uu on u and ijijn on
where 0v on u the above differential equation in the weak form
[17] is given as
22
dvdbvduvdv iiiiiiijji (237)
To perform the FE discretization of the weak form (237) means to divide the continuum volume into sub-elements where the displacement field in every element is approximated by shape functions )(xNI and nodal
displacements )(tuiI that is summation of their products [17]
)()()( xNtutxu IiIi (238)
By approximating the test functions with the same shape functions (Galerkin method) we obtain
0)(
)()(
)(
)(
)(
)(
int)(
int
int
ee
e
e
dNbdNff
NdNMM
x
NBdBff
fuMfv
TTexte
ext
Te
j
IjI
Te
extT
(239)
which must hold for an arbitrary v and which puts the FE equation in order
intffuM ext (240)
For a linear material C the FE equation that emerges is
23
)(
)(e
dCBBKKfKuuM TTeext (241)
224 Numerical procedure
For the induction hardening process three different analyses have been combined in one numerical procedure mechanical thermal-metallurgical and electromagnetic (EM) computations They are solved fully transiently Boundary conditions and material properties beside one unique geometric model were required by each of them
What is necessary to mention is that some characteristics of the material are interdependent The electric conductivity for instance depends on the temperature In addition all thermal properties depend on the temperature [18] The variation of the properties with the temperature makes the system to be non-linear
There is a high coupling grade between thermal and EM equations because the electrical and magnetic properties laws depend on temperature When the initial temperature is known the eddy current value is calculated and then used to compute the heat generated by the Joule effect [5] At each time step the convergence is checked Until a steady state between the heat and the temperature field is reached the temperature value will be recalculated for each magnetic sub-step
EM solver can be coupled with the thermal and mechanical solvers in order to take full advantage of their capabilities [7] Both the thermal and the EM solver run with implicit time integration For mechanical solver there are two time integration methods of explicit and implicit type
Explicit and implicit methods are numerical schemes for obtaining numerical solutions of time-dependent ordinary and partial differential equations as is required in computer simulations of physical processes Explicit methods calculate the state of a system at a later time from the state of the system at the current time while implicit methods find a solution by solving an equation involving both the current state of the system and the later one [19] Here follows the difference between explicit and implicit methods
Implicit method
o More accurate
24
o It has large time step increment
o Convergence of each load step can be controlled to avoid error accumulation
o Iteration may not converge
Explicit method
o Less accurate
o It has small time step
o There is error accumulation and the error is difficult to estimate
o Iteration converges
However the implicit type has been governing the mechanical solver for the induction process in this thesis
Now let us go back to the couplings For the electromagnetic and structure interaction both the mechanical and the EM solver have distinct time steps By linear interpolation the EM fields are evaluated at the mechanical time step The two solvers will interact at each electromagnetic time step The EM solver will communicate the Lorentz force to the mechanical solver [7] resulting in an extra force in the mechanic equation
Lorentzext FfDt
Du (242)
where is total charge density is electrical conductivity extf is the
external force while LorentzF is the Lorentz force In turn the displacements
and deformations of the conductors are returned by the mechanical solver
When it comes to the thermal coupling at each electromagnetic time step the EM solver will communicate the extra Joule heating power term and the thermal solver will communicate the temperature
Figure 22 shows the interactions between the different solvers in LS-DYNA
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
6
1 Introduction
11 Background
The induction hardening is one of the methods for heat treatment of steel workpieces The induction hardening can be used for both through-hardening and to selectively harden areas of a part or assembly When the method is used to harden only the surface of the parts it has been applied to various machine parts such as automobile components and toothed gears [1]
The classic method of hardening contains first heating to an austenitic state (austenite has a Face Centre Cubic ndash FCC atomic structure) and then cooling rapidly Let us assume the initial phase being ferritic-pearlitic Ferrite has a Body Centre Cubic structure (BCC) which can hold very little carbon typically 00001 at room temperature It can exist as either alpha or delta ferrite Pearlite is a mixture of alternate strips of ferrite and cementite in a single grain The name for this structure is derived from pearl appearance seen under a microscope A fully pearlitic structure occurs at 08 Carbon
During heating see Figure 12 two processes occur Firstly the cementite starts to dissolve and the cementite particles to shrink When the temperature rises above a critical value the ferrite starts to transform to austenite Austenite formation and cementite dissolution occur faster the higher the temperature The structure is fully austenitic above the A3 (Ac3) or Accm line (the upper line in the Iron Carbon Diagram) Figure 11
7
Figure 11 Iron Carbon Diagram
Figure 12 Induction heating of a part
During cooling from the austenitic state several different phase transformations may take place depending on how fast the cooling process is When steel is cooled sufficiently rapidly other structures do not have sufficient time to form and the austenite can be retained at low temperatures since the diffusion-dependent transformations proceed slowly When the temperature is sufficiently low the tendency of austenite to be transformed becomes so strong that the transformation takes place without diffusion Such a transformation is called diffusionless and can in principle occur with two different mechanisms namely massive and martensitic transformation [2]
Figure 13 Quenching (cooling) of a part
8
In a martensitic transformation FCC structure of austenite rapidly changes to BCC leaving insufficient time for the carbon to form pearlite This results in a distorted structure that has the appearance of fine needles Only the parts of a section that cool fast enough will form martensite in a thick section it will only form to a certain depth and if the shape is complex it may only form in small pockets The hardness of martensite is solely dependant on carbon content it is normally very high unless the carbon content is exceptionally low The martensitic transformation is of great practical significance since it is the martensite which gives steel its high degree of hardness and strength
In the induction hardening of our interest the surface of the workpiece is heated up over the austenitization temperature by the induction heating Figure 12 and transformed from the ferritic and pearlitic structure Figure 14 A to the austenite structure Figure 14 B The heating process is then followed by immediate quenching process Figure 13 and the surface of the workpiece is transformed from the austenitic to the martensitic phase Figure 14 C and thereby hardened The heating condition for the induction hardening can be determined experimentally or empirically for the workpiece of any shape [1]
Figure 14 Specimen microstructures of normalized steel A) Ferritic-Pearlitic B) Austenitic and C) Martensitic
9
Induction heating is the process of heating an electrically conducting object by electromagnetic induction where eddy currents are generated within the metal and resistance leads to Joule heating of the metal [6] This process is widely used in industrial operations due to its high efficiency precise control and more environmentally friendly properties [3] The induction heating has some characteristics compared to the traditional heating methods (such as furnace heating)
It has a precise depth of heating and the heating zone which is easier to control
It is easy to implement high power density fast heating high efficiency and low energy consumption
It is easy to control the high heating temperature
The conduction and infiltration of the heating temperature will be from the surface to the interior
There are no penetrating impurities since non-contact heating method is used
The burned part on the workpiece is smaller
The process is somewhat eco-friendly
It is easy to accomplish the automation of heating process
The quenching part of an induction hardening process is also an important part Cooling rates must be rapid in order to avoid softer undesirable structures such as pearlite and bainite Due to its importance the cooling portion of the induction hardening process deserves careful consideration particularly when specifying new induction equipment and processes Process parameters must be precisely controlled to assure consistent heat treatment results Excessive variation in these parameters will cause undesirable or inconsistent process results including problems with case depth hardness pattern and distortion [4] Water quench has been used for the problem in this thesis
12 Aim
Let us go to the main objective of this work Although the induction hardening process has many advantages the design of it which is usually based on experiments can be tiresome time-consuming and expensive
10
Luckily the fast development of the computer technology makes it possible to model the induction heat treatment process with numerical tools particularly with Finite Element Method (FEM) Nowadays a lot of engineers pay attention to this area
There are many FEM modeling works regarding either the heating or quenching heat treatment in the literature However numerical models of the integrated heat treatment ie both the induction heating and quenching are still gaining ground [5] Induction hardening is a complex physical process which has contributions from electrical magnetic thermal mechanical and metallurgical processes It is obvious that the complexity of the phenomena ndash including phase transformation and heat exchange makes the FEM analysis heavy and difficult
Different FEM softwares have been used for numerical studies of the induction hardening process In this study LS-DYNA has been used for simulations The electromagnetic field the eddy current and the temperature field have been calculated with the FEM and Boundary Element Method (BEM) In fact FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air thus no air mesh is needed The main study included
The mathematical description and the modeling of the induction heat treatment process
Solving the induction-hardening-modeling key technical issues
Simulating the induction hardening process with the existing commercial software LS-DYNA
Comparing the results of the simulation with the literature values and evaluating the softwarersquos capability
In short the aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The simulation results have been compared to literature results for evaluation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Here follows the model selected from a literature source [5] the induction heating and cooling of cylindrical workpiece The experimental setup is made of three parts the coil the bar and the cooling tool Figure 15
11
Figure 15 The experimental set-up
12
2 Induction and the corresponding numerical background
21 Induction process - Maxwell equations
The basic model is shown in Figure 21
Figure 21 Induction heating principle
The partial differential equations are used to solve the electromagnetic field distribution
In order to define the equations solved by the electromagnetic solver in LS-DYNA we start with the Maxwell equations [7]
t
BE
(21)
t
EjH
0 (22)
0 B
(23)
13
0
E
(24)
sjEj
(25)
HB
0 (26)
where E
is electric field B
is magnetic flux density t is time H
is
magnetic field intensity j
is current density 0 is permittivity of free
space is total charge density is electric conductivity sj
is source
current density and 0 is permeability of free space
The eddy current approximation used here implies a divergence-free current
density and no charge accumulation thus resulting in 00
t
E
and 0
Equations (22) and (24) in the eddy current approximation give
jH
(27)
0 E
(28)
0 j
(29)
The divergence condition given by equation (23) allows writing B
as
AB
(210)
where A
is the magnetic vector potential [8] Equation (21) then implies that the electric field is given by
t
AE
(211)
14
where is the electric scalar potential
Equation (210) leaves a mathematical degree of freedom to A
(if A
is
transformed to a given
A then Equation (210) remains valid) Therefore the introduction of a gauge ie a particular choice of the scalar and vector potentials is needed Gauge choosing denotes a mathematical procedure for coping with redundant degrees of freedom in field variables The gauge chosen here is the generalized Coulomb gauge
0 A
(212)
Equations (25) (29) (211) and (212) give
0
(213)
Equations (25) (27) (211) and (210) give
sjAt
A
1
(214)
Equation (213) and Equation (214) are the two equations constituting the system that will be solved where A
and are the two unknowns of the
problem [7]
211 Skin effect and skin depth
Skin effect is the tendency of an alternating electric current (AC) to become distributed within a conductor such that the current density is largest near the surface of the conductor and decreases with greater depths in the conductor [9]
Skin effect is associated with the current flowing mainly at the skin of the conductor at an average depth called the skin depth The skin depth is
15
defined as the depth at which the electromagnetic field in a conducting material has decreased to 037 of its value just outside the material which describes the electric and magnetic fields The formula for the skin depth is given by
ff rr
503
)2(
22
0
(215)
where is the skin depth f is the frequency is the average electrical
resistivity and r is the average relative permeability
212 Proximity effect
A changing magnetic field will influence the distribution of an electric current flowing within an electrical conductor by electromagnetic induction When an alternating current flows through an isolated conductor it creates an associated alternating magnetic field around it The alternating magnetic field induces eddy currents in adjacent conductors altering the overall distribution of current flowing through them ndash the distribution of current within the conductor will be constrained to smaller regions Subsequently the resistance is increased in those regions The resulting current crowding is termed the proximity effect Usually the current is concentrated in the areas of the conductor furthest away from nearby conductors carrying current in the same direction [10]
Thus since in our case the inductor is a coil the maximum current density will be at the inner side of the coil [3] So the inner side of the coil will be used to heat the workpiece which will get faster temperature increase and will be more efficient
22 Numerical basis of the induction process
All the physical phenomena encountered in engineering mechanics are modeled by differential equations Usually it is difficult to obtain accurate analytical solution of the differential equation However the numerical solution could be calculated but only when boundary conditions and initial
16
conditions under specific situations were given The following numerical methods are used to model the induction process in LS-DYNA
Finite Element Method
The FEM is today a powerful (often the most powerful) tool for numerical solution of any differential equation whether this arises from structural mechanics fluid mechanics thermodynamics biology ecology or any other field of science [11]
The finite element method is a numerical approach by which general differential equations can be solved in an approximate manner [12] A domain of interest is represented as an assembly of finite elements The FEM is useful for problems with complicated geometries loadings and material properties where analytical solutions cannot be obtained [13]
The main steps in the general FE formulation and solution of a physical problem are [11]
o Establish the strong form of the governing differential equation
o Transform this differential equation into the weak form
o Choose trial functions for the unknown function that is choose element type(s) and mesh the solution domain
o Choose weight functions and establish the system of algebraic equations for each element (element equations)
o Assemble these element systems into the global system of algebraic equations
o Introduce boundary conditions into the global system of algebraic equations
o Solve the system of algebraic equations and present the results or use them for further calculations
Boundary Element Method
The boundary element method (BEM) is a numerical computational method of solving linear partial differential equations which have been formulated as integral equations BEM attempts to use the given boundary conditions to fit only boundary values into the integral equation Once this is done the integral equation can then be used again to calculate numerically solution at any desired point in the interior of the solution domain The boundary
17
element method is often more efficient than other methods including FEM in terms of computational resources for problems where there is a small surfacevolume ratio Conceptually it works by constructing a mesh over the modeled surface However for many problems boundary element methods are significantly less suitable and efficient than volume-discretization methods [14]
In numerical computations of the problem in this thesis with LS-DYNA FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air
221 FEM model for electromagnetic field
In LS-DYNA equation (213) is projected on the 0W forms (0-forms are continuous scalar basis functions that have a well defined gradient the gradient of a 0-form being a 1- form) and equation (214) is projected on
the 1W
forms (1-forms are vector basis functions with continuous tangential components but discontinuous normal components) They have a well defined curl the curl of a 1-form being a 2-form) giving after integrating by part the following weak formulations [15]
00 dW
(216)
dWAndW
dWAdWt
A
11
11
)(
1
(217)
where d an element of volume and the surface of with n
outer normal to
The and A
decompositions on respectfully 0W and 1W
give
0iiw (218)
1iiwaA
(219)
18
When replacing and A
in equation (216) and (217) by (218) and (219) one gets
0)(0 S (220)
SaDaSt
aM
)()
1()( 0111
(221)
where
the stiffness matrix of the 0-forms is given by
dWWjiS ji000 ))((
(222)
the mass matrix of the 1-forms is given by
dWWjiM ji111 ))((
(223)
the stiffness matrix of the 1-forms is given by
dWWjiS ji )()(1
))(1
( 111
(224)
the derivative matrix of the 0-1-forms is given by
dWWjiD ji )())(( 1001
(225)
the outside stiffness matrix is given by
19
dWWnjiS ji11)(
1))(
1(
(226)
where is the magnetic permeability n
is the normal vector is the volume and is the boundary surface of volume
Equation (220) and (221) form the FEM system with and a being the unknowns From this system only the outside stiffness matrix cannot be directly computed The calculation of this matrix will be made possible through the definition of the BEM system [7] The BEM system is used for the air and will not be shown in this report More information about it could be found in [7]
222 FEM model for temperature field
The steady state or transient temperature field on three dimensional geometries can also be solved by LS-DYNA Material properties may be temperature dependent and either isotopic or orthotropic A variety of time and temperature dependent boundary conditions can be specified including temperature flux convection and radiation The implementation of heat conduction into LS-DYNA is based on the work of Shapiro [16]
The differential equations of conduction of heat in a three-dimensional continuum is given by
Qkt
cijij
(227)
where )( txi is temperature )( ix is density )( ixcc is
the specific heat )( iijij xkk is thermal conductivity )( ixQQ is
internal heat generation rate per unit volume
The boundary conditions are
s on 1 (228)
20
ijij nk on 2 (229)
Initial conditions at 0t are given by
)(0 ix at 0tt (230)
where )(txx ii are coordinates as a function of time is prescribed
temperature on 1 and in is normal vector to 2
Equations (227-230) represent the strong form of a boundary value problem to be solved for the temperature field within the solid continuum [16]
The finite element method provides the following equations for the numerical solution of equations (227-230)
nnnnnnn HFHt
C
1 (231)
e
jie
eij
e
dcNNCC (232)
ejiji
T
e
eij
ee
dNNdNKNHH (233)
eigi
e
ei
ee
dNdqNFF (234)
where and are the parameters that are different when using different methods like Crank-Nicolson Galerkin and so on The parameter is taken to be in the interval [01] C H and F are the element stiffness load and boundary matrices respectively N is the element shape functions gq is the heat flow K is the thermal conductivity tensor
21
The boundary conditions for temperature flux convection and radiation are
)(
)(
)(
42
4112 TTF
n
T
TThn
T
qn
Tk
tzyxfT
w
sz
(235)
where T is the temperature k is the thermal conductivity n is the normal direction of the boundary szq
is the heat flux vector h is the convective
heat transfer coefficient wT is the surface temperature of the solid T is
the fluid temperature is the emissivity is the Stefan Boltzmann constant
223 FEM model for mechanical field
The equations that govern analyses of the behavior of a solid continuum are those of momentum conservation ie the equations of motion For an analysis of small deformation of a solid continuum these are (in tensor form) [17]
iijij ub (236)
where ij is the Cauchy stress tensor ib the body force vector per unit
volume the density and iu the displacement vector
To establish a weak form from the strong one we multiply (236) by an arbitrary velocity ie the test function iv and integrate over the region
By introducing two boundary conditions ii uu on u and ijijn on
where 0v on u the above differential equation in the weak form
[17] is given as
22
dvdbvduvdv iiiiiiijji (237)
To perform the FE discretization of the weak form (237) means to divide the continuum volume into sub-elements where the displacement field in every element is approximated by shape functions )(xNI and nodal
displacements )(tuiI that is summation of their products [17]
)()()( xNtutxu IiIi (238)
By approximating the test functions with the same shape functions (Galerkin method) we obtain
0)(
)()(
)(
)(
)(
)(
int)(
int
int
ee
e
e
dNbdNff
NdNMM
x
NBdBff
fuMfv
TTexte
ext
Te
j
IjI
Te
extT
(239)
which must hold for an arbitrary v and which puts the FE equation in order
intffuM ext (240)
For a linear material C the FE equation that emerges is
23
)(
)(e
dCBBKKfKuuM TTeext (241)
224 Numerical procedure
For the induction hardening process three different analyses have been combined in one numerical procedure mechanical thermal-metallurgical and electromagnetic (EM) computations They are solved fully transiently Boundary conditions and material properties beside one unique geometric model were required by each of them
What is necessary to mention is that some characteristics of the material are interdependent The electric conductivity for instance depends on the temperature In addition all thermal properties depend on the temperature [18] The variation of the properties with the temperature makes the system to be non-linear
There is a high coupling grade between thermal and EM equations because the electrical and magnetic properties laws depend on temperature When the initial temperature is known the eddy current value is calculated and then used to compute the heat generated by the Joule effect [5] At each time step the convergence is checked Until a steady state between the heat and the temperature field is reached the temperature value will be recalculated for each magnetic sub-step
EM solver can be coupled with the thermal and mechanical solvers in order to take full advantage of their capabilities [7] Both the thermal and the EM solver run with implicit time integration For mechanical solver there are two time integration methods of explicit and implicit type
Explicit and implicit methods are numerical schemes for obtaining numerical solutions of time-dependent ordinary and partial differential equations as is required in computer simulations of physical processes Explicit methods calculate the state of a system at a later time from the state of the system at the current time while implicit methods find a solution by solving an equation involving both the current state of the system and the later one [19] Here follows the difference between explicit and implicit methods
Implicit method
o More accurate
24
o It has large time step increment
o Convergence of each load step can be controlled to avoid error accumulation
o Iteration may not converge
Explicit method
o Less accurate
o It has small time step
o There is error accumulation and the error is difficult to estimate
o Iteration converges
However the implicit type has been governing the mechanical solver for the induction process in this thesis
Now let us go back to the couplings For the electromagnetic and structure interaction both the mechanical and the EM solver have distinct time steps By linear interpolation the EM fields are evaluated at the mechanical time step The two solvers will interact at each electromagnetic time step The EM solver will communicate the Lorentz force to the mechanical solver [7] resulting in an extra force in the mechanic equation
Lorentzext FfDt
Du (242)
where is total charge density is electrical conductivity extf is the
external force while LorentzF is the Lorentz force In turn the displacements
and deformations of the conductors are returned by the mechanical solver
When it comes to the thermal coupling at each electromagnetic time step the EM solver will communicate the extra Joule heating power term and the thermal solver will communicate the temperature
Figure 22 shows the interactions between the different solvers in LS-DYNA
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
7
Figure 11 Iron Carbon Diagram
Figure 12 Induction heating of a part
During cooling from the austenitic state several different phase transformations may take place depending on how fast the cooling process is When steel is cooled sufficiently rapidly other structures do not have sufficient time to form and the austenite can be retained at low temperatures since the diffusion-dependent transformations proceed slowly When the temperature is sufficiently low the tendency of austenite to be transformed becomes so strong that the transformation takes place without diffusion Such a transformation is called diffusionless and can in principle occur with two different mechanisms namely massive and martensitic transformation [2]
Figure 13 Quenching (cooling) of a part
8
In a martensitic transformation FCC structure of austenite rapidly changes to BCC leaving insufficient time for the carbon to form pearlite This results in a distorted structure that has the appearance of fine needles Only the parts of a section that cool fast enough will form martensite in a thick section it will only form to a certain depth and if the shape is complex it may only form in small pockets The hardness of martensite is solely dependant on carbon content it is normally very high unless the carbon content is exceptionally low The martensitic transformation is of great practical significance since it is the martensite which gives steel its high degree of hardness and strength
In the induction hardening of our interest the surface of the workpiece is heated up over the austenitization temperature by the induction heating Figure 12 and transformed from the ferritic and pearlitic structure Figure 14 A to the austenite structure Figure 14 B The heating process is then followed by immediate quenching process Figure 13 and the surface of the workpiece is transformed from the austenitic to the martensitic phase Figure 14 C and thereby hardened The heating condition for the induction hardening can be determined experimentally or empirically for the workpiece of any shape [1]
Figure 14 Specimen microstructures of normalized steel A) Ferritic-Pearlitic B) Austenitic and C) Martensitic
9
Induction heating is the process of heating an electrically conducting object by electromagnetic induction where eddy currents are generated within the metal and resistance leads to Joule heating of the metal [6] This process is widely used in industrial operations due to its high efficiency precise control and more environmentally friendly properties [3] The induction heating has some characteristics compared to the traditional heating methods (such as furnace heating)
It has a precise depth of heating and the heating zone which is easier to control
It is easy to implement high power density fast heating high efficiency and low energy consumption
It is easy to control the high heating temperature
The conduction and infiltration of the heating temperature will be from the surface to the interior
There are no penetrating impurities since non-contact heating method is used
The burned part on the workpiece is smaller
The process is somewhat eco-friendly
It is easy to accomplish the automation of heating process
The quenching part of an induction hardening process is also an important part Cooling rates must be rapid in order to avoid softer undesirable structures such as pearlite and bainite Due to its importance the cooling portion of the induction hardening process deserves careful consideration particularly when specifying new induction equipment and processes Process parameters must be precisely controlled to assure consistent heat treatment results Excessive variation in these parameters will cause undesirable or inconsistent process results including problems with case depth hardness pattern and distortion [4] Water quench has been used for the problem in this thesis
12 Aim
Let us go to the main objective of this work Although the induction hardening process has many advantages the design of it which is usually based on experiments can be tiresome time-consuming and expensive
10
Luckily the fast development of the computer technology makes it possible to model the induction heat treatment process with numerical tools particularly with Finite Element Method (FEM) Nowadays a lot of engineers pay attention to this area
There are many FEM modeling works regarding either the heating or quenching heat treatment in the literature However numerical models of the integrated heat treatment ie both the induction heating and quenching are still gaining ground [5] Induction hardening is a complex physical process which has contributions from electrical magnetic thermal mechanical and metallurgical processes It is obvious that the complexity of the phenomena ndash including phase transformation and heat exchange makes the FEM analysis heavy and difficult
Different FEM softwares have been used for numerical studies of the induction hardening process In this study LS-DYNA has been used for simulations The electromagnetic field the eddy current and the temperature field have been calculated with the FEM and Boundary Element Method (BEM) In fact FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air thus no air mesh is needed The main study included
The mathematical description and the modeling of the induction heat treatment process
Solving the induction-hardening-modeling key technical issues
Simulating the induction hardening process with the existing commercial software LS-DYNA
Comparing the results of the simulation with the literature values and evaluating the softwarersquos capability
In short the aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The simulation results have been compared to literature results for evaluation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Here follows the model selected from a literature source [5] the induction heating and cooling of cylindrical workpiece The experimental setup is made of three parts the coil the bar and the cooling tool Figure 15
11
Figure 15 The experimental set-up
12
2 Induction and the corresponding numerical background
21 Induction process - Maxwell equations
The basic model is shown in Figure 21
Figure 21 Induction heating principle
The partial differential equations are used to solve the electromagnetic field distribution
In order to define the equations solved by the electromagnetic solver in LS-DYNA we start with the Maxwell equations [7]
t
BE
(21)
t
EjH
0 (22)
0 B
(23)
13
0
E
(24)
sjEj
(25)
HB
0 (26)
where E
is electric field B
is magnetic flux density t is time H
is
magnetic field intensity j
is current density 0 is permittivity of free
space is total charge density is electric conductivity sj
is source
current density and 0 is permeability of free space
The eddy current approximation used here implies a divergence-free current
density and no charge accumulation thus resulting in 00
t
E
and 0
Equations (22) and (24) in the eddy current approximation give
jH
(27)
0 E
(28)
0 j
(29)
The divergence condition given by equation (23) allows writing B
as
AB
(210)
where A
is the magnetic vector potential [8] Equation (21) then implies that the electric field is given by
t
AE
(211)
14
where is the electric scalar potential
Equation (210) leaves a mathematical degree of freedom to A
(if A
is
transformed to a given
A then Equation (210) remains valid) Therefore the introduction of a gauge ie a particular choice of the scalar and vector potentials is needed Gauge choosing denotes a mathematical procedure for coping with redundant degrees of freedom in field variables The gauge chosen here is the generalized Coulomb gauge
0 A
(212)
Equations (25) (29) (211) and (212) give
0
(213)
Equations (25) (27) (211) and (210) give
sjAt
A
1
(214)
Equation (213) and Equation (214) are the two equations constituting the system that will be solved where A
and are the two unknowns of the
problem [7]
211 Skin effect and skin depth
Skin effect is the tendency of an alternating electric current (AC) to become distributed within a conductor such that the current density is largest near the surface of the conductor and decreases with greater depths in the conductor [9]
Skin effect is associated with the current flowing mainly at the skin of the conductor at an average depth called the skin depth The skin depth is
15
defined as the depth at which the electromagnetic field in a conducting material has decreased to 037 of its value just outside the material which describes the electric and magnetic fields The formula for the skin depth is given by
ff rr
503
)2(
22
0
(215)
where is the skin depth f is the frequency is the average electrical
resistivity and r is the average relative permeability
212 Proximity effect
A changing magnetic field will influence the distribution of an electric current flowing within an electrical conductor by electromagnetic induction When an alternating current flows through an isolated conductor it creates an associated alternating magnetic field around it The alternating magnetic field induces eddy currents in adjacent conductors altering the overall distribution of current flowing through them ndash the distribution of current within the conductor will be constrained to smaller regions Subsequently the resistance is increased in those regions The resulting current crowding is termed the proximity effect Usually the current is concentrated in the areas of the conductor furthest away from nearby conductors carrying current in the same direction [10]
Thus since in our case the inductor is a coil the maximum current density will be at the inner side of the coil [3] So the inner side of the coil will be used to heat the workpiece which will get faster temperature increase and will be more efficient
22 Numerical basis of the induction process
All the physical phenomena encountered in engineering mechanics are modeled by differential equations Usually it is difficult to obtain accurate analytical solution of the differential equation However the numerical solution could be calculated but only when boundary conditions and initial
16
conditions under specific situations were given The following numerical methods are used to model the induction process in LS-DYNA
Finite Element Method
The FEM is today a powerful (often the most powerful) tool for numerical solution of any differential equation whether this arises from structural mechanics fluid mechanics thermodynamics biology ecology or any other field of science [11]
The finite element method is a numerical approach by which general differential equations can be solved in an approximate manner [12] A domain of interest is represented as an assembly of finite elements The FEM is useful for problems with complicated geometries loadings and material properties where analytical solutions cannot be obtained [13]
The main steps in the general FE formulation and solution of a physical problem are [11]
o Establish the strong form of the governing differential equation
o Transform this differential equation into the weak form
o Choose trial functions for the unknown function that is choose element type(s) and mesh the solution domain
o Choose weight functions and establish the system of algebraic equations for each element (element equations)
o Assemble these element systems into the global system of algebraic equations
o Introduce boundary conditions into the global system of algebraic equations
o Solve the system of algebraic equations and present the results or use them for further calculations
Boundary Element Method
The boundary element method (BEM) is a numerical computational method of solving linear partial differential equations which have been formulated as integral equations BEM attempts to use the given boundary conditions to fit only boundary values into the integral equation Once this is done the integral equation can then be used again to calculate numerically solution at any desired point in the interior of the solution domain The boundary
17
element method is often more efficient than other methods including FEM in terms of computational resources for problems where there is a small surfacevolume ratio Conceptually it works by constructing a mesh over the modeled surface However for many problems boundary element methods are significantly less suitable and efficient than volume-discretization methods [14]
In numerical computations of the problem in this thesis with LS-DYNA FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air
221 FEM model for electromagnetic field
In LS-DYNA equation (213) is projected on the 0W forms (0-forms are continuous scalar basis functions that have a well defined gradient the gradient of a 0-form being a 1- form) and equation (214) is projected on
the 1W
forms (1-forms are vector basis functions with continuous tangential components but discontinuous normal components) They have a well defined curl the curl of a 1-form being a 2-form) giving after integrating by part the following weak formulations [15]
00 dW
(216)
dWAndW
dWAdWt
A
11
11
)(
1
(217)
where d an element of volume and the surface of with n
outer normal to
The and A
decompositions on respectfully 0W and 1W
give
0iiw (218)
1iiwaA
(219)
18
When replacing and A
in equation (216) and (217) by (218) and (219) one gets
0)(0 S (220)
SaDaSt
aM
)()
1()( 0111
(221)
where
the stiffness matrix of the 0-forms is given by
dWWjiS ji000 ))((
(222)
the mass matrix of the 1-forms is given by
dWWjiM ji111 ))((
(223)
the stiffness matrix of the 1-forms is given by
dWWjiS ji )()(1
))(1
( 111
(224)
the derivative matrix of the 0-1-forms is given by
dWWjiD ji )())(( 1001
(225)
the outside stiffness matrix is given by
19
dWWnjiS ji11)(
1))(
1(
(226)
where is the magnetic permeability n
is the normal vector is the volume and is the boundary surface of volume
Equation (220) and (221) form the FEM system with and a being the unknowns From this system only the outside stiffness matrix cannot be directly computed The calculation of this matrix will be made possible through the definition of the BEM system [7] The BEM system is used for the air and will not be shown in this report More information about it could be found in [7]
222 FEM model for temperature field
The steady state or transient temperature field on three dimensional geometries can also be solved by LS-DYNA Material properties may be temperature dependent and either isotopic or orthotropic A variety of time and temperature dependent boundary conditions can be specified including temperature flux convection and radiation The implementation of heat conduction into LS-DYNA is based on the work of Shapiro [16]
The differential equations of conduction of heat in a three-dimensional continuum is given by
Qkt
cijij
(227)
where )( txi is temperature )( ix is density )( ixcc is
the specific heat )( iijij xkk is thermal conductivity )( ixQQ is
internal heat generation rate per unit volume
The boundary conditions are
s on 1 (228)
20
ijij nk on 2 (229)
Initial conditions at 0t are given by
)(0 ix at 0tt (230)
where )(txx ii are coordinates as a function of time is prescribed
temperature on 1 and in is normal vector to 2
Equations (227-230) represent the strong form of a boundary value problem to be solved for the temperature field within the solid continuum [16]
The finite element method provides the following equations for the numerical solution of equations (227-230)
nnnnnnn HFHt
C
1 (231)
e
jie
eij
e
dcNNCC (232)
ejiji
T
e
eij
ee
dNNdNKNHH (233)
eigi
e
ei
ee
dNdqNFF (234)
where and are the parameters that are different when using different methods like Crank-Nicolson Galerkin and so on The parameter is taken to be in the interval [01] C H and F are the element stiffness load and boundary matrices respectively N is the element shape functions gq is the heat flow K is the thermal conductivity tensor
21
The boundary conditions for temperature flux convection and radiation are
)(
)(
)(
42
4112 TTF
n
T
TThn
T
qn
Tk
tzyxfT
w
sz
(235)
where T is the temperature k is the thermal conductivity n is the normal direction of the boundary szq
is the heat flux vector h is the convective
heat transfer coefficient wT is the surface temperature of the solid T is
the fluid temperature is the emissivity is the Stefan Boltzmann constant
223 FEM model for mechanical field
The equations that govern analyses of the behavior of a solid continuum are those of momentum conservation ie the equations of motion For an analysis of small deformation of a solid continuum these are (in tensor form) [17]
iijij ub (236)
where ij is the Cauchy stress tensor ib the body force vector per unit
volume the density and iu the displacement vector
To establish a weak form from the strong one we multiply (236) by an arbitrary velocity ie the test function iv and integrate over the region
By introducing two boundary conditions ii uu on u and ijijn on
where 0v on u the above differential equation in the weak form
[17] is given as
22
dvdbvduvdv iiiiiiijji (237)
To perform the FE discretization of the weak form (237) means to divide the continuum volume into sub-elements where the displacement field in every element is approximated by shape functions )(xNI and nodal
displacements )(tuiI that is summation of their products [17]
)()()( xNtutxu IiIi (238)
By approximating the test functions with the same shape functions (Galerkin method) we obtain
0)(
)()(
)(
)(
)(
)(
int)(
int
int
ee
e
e
dNbdNff
NdNMM
x
NBdBff
fuMfv
TTexte
ext
Te
j
IjI
Te
extT
(239)
which must hold for an arbitrary v and which puts the FE equation in order
intffuM ext (240)
For a linear material C the FE equation that emerges is
23
)(
)(e
dCBBKKfKuuM TTeext (241)
224 Numerical procedure
For the induction hardening process three different analyses have been combined in one numerical procedure mechanical thermal-metallurgical and electromagnetic (EM) computations They are solved fully transiently Boundary conditions and material properties beside one unique geometric model were required by each of them
What is necessary to mention is that some characteristics of the material are interdependent The electric conductivity for instance depends on the temperature In addition all thermal properties depend on the temperature [18] The variation of the properties with the temperature makes the system to be non-linear
There is a high coupling grade between thermal and EM equations because the electrical and magnetic properties laws depend on temperature When the initial temperature is known the eddy current value is calculated and then used to compute the heat generated by the Joule effect [5] At each time step the convergence is checked Until a steady state between the heat and the temperature field is reached the temperature value will be recalculated for each magnetic sub-step
EM solver can be coupled with the thermal and mechanical solvers in order to take full advantage of their capabilities [7] Both the thermal and the EM solver run with implicit time integration For mechanical solver there are two time integration methods of explicit and implicit type
Explicit and implicit methods are numerical schemes for obtaining numerical solutions of time-dependent ordinary and partial differential equations as is required in computer simulations of physical processes Explicit methods calculate the state of a system at a later time from the state of the system at the current time while implicit methods find a solution by solving an equation involving both the current state of the system and the later one [19] Here follows the difference between explicit and implicit methods
Implicit method
o More accurate
24
o It has large time step increment
o Convergence of each load step can be controlled to avoid error accumulation
o Iteration may not converge
Explicit method
o Less accurate
o It has small time step
o There is error accumulation and the error is difficult to estimate
o Iteration converges
However the implicit type has been governing the mechanical solver for the induction process in this thesis
Now let us go back to the couplings For the electromagnetic and structure interaction both the mechanical and the EM solver have distinct time steps By linear interpolation the EM fields are evaluated at the mechanical time step The two solvers will interact at each electromagnetic time step The EM solver will communicate the Lorentz force to the mechanical solver [7] resulting in an extra force in the mechanic equation
Lorentzext FfDt
Du (242)
where is total charge density is electrical conductivity extf is the
external force while LorentzF is the Lorentz force In turn the displacements
and deformations of the conductors are returned by the mechanical solver
When it comes to the thermal coupling at each electromagnetic time step the EM solver will communicate the extra Joule heating power term and the thermal solver will communicate the temperature
Figure 22 shows the interactions between the different solvers in LS-DYNA
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
8
In a martensitic transformation FCC structure of austenite rapidly changes to BCC leaving insufficient time for the carbon to form pearlite This results in a distorted structure that has the appearance of fine needles Only the parts of a section that cool fast enough will form martensite in a thick section it will only form to a certain depth and if the shape is complex it may only form in small pockets The hardness of martensite is solely dependant on carbon content it is normally very high unless the carbon content is exceptionally low The martensitic transformation is of great practical significance since it is the martensite which gives steel its high degree of hardness and strength
In the induction hardening of our interest the surface of the workpiece is heated up over the austenitization temperature by the induction heating Figure 12 and transformed from the ferritic and pearlitic structure Figure 14 A to the austenite structure Figure 14 B The heating process is then followed by immediate quenching process Figure 13 and the surface of the workpiece is transformed from the austenitic to the martensitic phase Figure 14 C and thereby hardened The heating condition for the induction hardening can be determined experimentally or empirically for the workpiece of any shape [1]
Figure 14 Specimen microstructures of normalized steel A) Ferritic-Pearlitic B) Austenitic and C) Martensitic
9
Induction heating is the process of heating an electrically conducting object by electromagnetic induction where eddy currents are generated within the metal and resistance leads to Joule heating of the metal [6] This process is widely used in industrial operations due to its high efficiency precise control and more environmentally friendly properties [3] The induction heating has some characteristics compared to the traditional heating methods (such as furnace heating)
It has a precise depth of heating and the heating zone which is easier to control
It is easy to implement high power density fast heating high efficiency and low energy consumption
It is easy to control the high heating temperature
The conduction and infiltration of the heating temperature will be from the surface to the interior
There are no penetrating impurities since non-contact heating method is used
The burned part on the workpiece is smaller
The process is somewhat eco-friendly
It is easy to accomplish the automation of heating process
The quenching part of an induction hardening process is also an important part Cooling rates must be rapid in order to avoid softer undesirable structures such as pearlite and bainite Due to its importance the cooling portion of the induction hardening process deserves careful consideration particularly when specifying new induction equipment and processes Process parameters must be precisely controlled to assure consistent heat treatment results Excessive variation in these parameters will cause undesirable or inconsistent process results including problems with case depth hardness pattern and distortion [4] Water quench has been used for the problem in this thesis
12 Aim
Let us go to the main objective of this work Although the induction hardening process has many advantages the design of it which is usually based on experiments can be tiresome time-consuming and expensive
10
Luckily the fast development of the computer technology makes it possible to model the induction heat treatment process with numerical tools particularly with Finite Element Method (FEM) Nowadays a lot of engineers pay attention to this area
There are many FEM modeling works regarding either the heating or quenching heat treatment in the literature However numerical models of the integrated heat treatment ie both the induction heating and quenching are still gaining ground [5] Induction hardening is a complex physical process which has contributions from electrical magnetic thermal mechanical and metallurgical processes It is obvious that the complexity of the phenomena ndash including phase transformation and heat exchange makes the FEM analysis heavy and difficult
Different FEM softwares have been used for numerical studies of the induction hardening process In this study LS-DYNA has been used for simulations The electromagnetic field the eddy current and the temperature field have been calculated with the FEM and Boundary Element Method (BEM) In fact FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air thus no air mesh is needed The main study included
The mathematical description and the modeling of the induction heat treatment process
Solving the induction-hardening-modeling key technical issues
Simulating the induction hardening process with the existing commercial software LS-DYNA
Comparing the results of the simulation with the literature values and evaluating the softwarersquos capability
In short the aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The simulation results have been compared to literature results for evaluation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Here follows the model selected from a literature source [5] the induction heating and cooling of cylindrical workpiece The experimental setup is made of three parts the coil the bar and the cooling tool Figure 15
11
Figure 15 The experimental set-up
12
2 Induction and the corresponding numerical background
21 Induction process - Maxwell equations
The basic model is shown in Figure 21
Figure 21 Induction heating principle
The partial differential equations are used to solve the electromagnetic field distribution
In order to define the equations solved by the electromagnetic solver in LS-DYNA we start with the Maxwell equations [7]
t
BE
(21)
t
EjH
0 (22)
0 B
(23)
13
0
E
(24)
sjEj
(25)
HB
0 (26)
where E
is electric field B
is magnetic flux density t is time H
is
magnetic field intensity j
is current density 0 is permittivity of free
space is total charge density is electric conductivity sj
is source
current density and 0 is permeability of free space
The eddy current approximation used here implies a divergence-free current
density and no charge accumulation thus resulting in 00
t
E
and 0
Equations (22) and (24) in the eddy current approximation give
jH
(27)
0 E
(28)
0 j
(29)
The divergence condition given by equation (23) allows writing B
as
AB
(210)
where A
is the magnetic vector potential [8] Equation (21) then implies that the electric field is given by
t
AE
(211)
14
where is the electric scalar potential
Equation (210) leaves a mathematical degree of freedom to A
(if A
is
transformed to a given
A then Equation (210) remains valid) Therefore the introduction of a gauge ie a particular choice of the scalar and vector potentials is needed Gauge choosing denotes a mathematical procedure for coping with redundant degrees of freedom in field variables The gauge chosen here is the generalized Coulomb gauge
0 A
(212)
Equations (25) (29) (211) and (212) give
0
(213)
Equations (25) (27) (211) and (210) give
sjAt
A
1
(214)
Equation (213) and Equation (214) are the two equations constituting the system that will be solved where A
and are the two unknowns of the
problem [7]
211 Skin effect and skin depth
Skin effect is the tendency of an alternating electric current (AC) to become distributed within a conductor such that the current density is largest near the surface of the conductor and decreases with greater depths in the conductor [9]
Skin effect is associated with the current flowing mainly at the skin of the conductor at an average depth called the skin depth The skin depth is
15
defined as the depth at which the electromagnetic field in a conducting material has decreased to 037 of its value just outside the material which describes the electric and magnetic fields The formula for the skin depth is given by
ff rr
503
)2(
22
0
(215)
where is the skin depth f is the frequency is the average electrical
resistivity and r is the average relative permeability
212 Proximity effect
A changing magnetic field will influence the distribution of an electric current flowing within an electrical conductor by electromagnetic induction When an alternating current flows through an isolated conductor it creates an associated alternating magnetic field around it The alternating magnetic field induces eddy currents in adjacent conductors altering the overall distribution of current flowing through them ndash the distribution of current within the conductor will be constrained to smaller regions Subsequently the resistance is increased in those regions The resulting current crowding is termed the proximity effect Usually the current is concentrated in the areas of the conductor furthest away from nearby conductors carrying current in the same direction [10]
Thus since in our case the inductor is a coil the maximum current density will be at the inner side of the coil [3] So the inner side of the coil will be used to heat the workpiece which will get faster temperature increase and will be more efficient
22 Numerical basis of the induction process
All the physical phenomena encountered in engineering mechanics are modeled by differential equations Usually it is difficult to obtain accurate analytical solution of the differential equation However the numerical solution could be calculated but only when boundary conditions and initial
16
conditions under specific situations were given The following numerical methods are used to model the induction process in LS-DYNA
Finite Element Method
The FEM is today a powerful (often the most powerful) tool for numerical solution of any differential equation whether this arises from structural mechanics fluid mechanics thermodynamics biology ecology or any other field of science [11]
The finite element method is a numerical approach by which general differential equations can be solved in an approximate manner [12] A domain of interest is represented as an assembly of finite elements The FEM is useful for problems with complicated geometries loadings and material properties where analytical solutions cannot be obtained [13]
The main steps in the general FE formulation and solution of a physical problem are [11]
o Establish the strong form of the governing differential equation
o Transform this differential equation into the weak form
o Choose trial functions for the unknown function that is choose element type(s) and mesh the solution domain
o Choose weight functions and establish the system of algebraic equations for each element (element equations)
o Assemble these element systems into the global system of algebraic equations
o Introduce boundary conditions into the global system of algebraic equations
o Solve the system of algebraic equations and present the results or use them for further calculations
Boundary Element Method
The boundary element method (BEM) is a numerical computational method of solving linear partial differential equations which have been formulated as integral equations BEM attempts to use the given boundary conditions to fit only boundary values into the integral equation Once this is done the integral equation can then be used again to calculate numerically solution at any desired point in the interior of the solution domain The boundary
17
element method is often more efficient than other methods including FEM in terms of computational resources for problems where there is a small surfacevolume ratio Conceptually it works by constructing a mesh over the modeled surface However for many problems boundary element methods are significantly less suitable and efficient than volume-discretization methods [14]
In numerical computations of the problem in this thesis with LS-DYNA FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air
221 FEM model for electromagnetic field
In LS-DYNA equation (213) is projected on the 0W forms (0-forms are continuous scalar basis functions that have a well defined gradient the gradient of a 0-form being a 1- form) and equation (214) is projected on
the 1W
forms (1-forms are vector basis functions with continuous tangential components but discontinuous normal components) They have a well defined curl the curl of a 1-form being a 2-form) giving after integrating by part the following weak formulations [15]
00 dW
(216)
dWAndW
dWAdWt
A
11
11
)(
1
(217)
where d an element of volume and the surface of with n
outer normal to
The and A
decompositions on respectfully 0W and 1W
give
0iiw (218)
1iiwaA
(219)
18
When replacing and A
in equation (216) and (217) by (218) and (219) one gets
0)(0 S (220)
SaDaSt
aM
)()
1()( 0111
(221)
where
the stiffness matrix of the 0-forms is given by
dWWjiS ji000 ))((
(222)
the mass matrix of the 1-forms is given by
dWWjiM ji111 ))((
(223)
the stiffness matrix of the 1-forms is given by
dWWjiS ji )()(1
))(1
( 111
(224)
the derivative matrix of the 0-1-forms is given by
dWWjiD ji )())(( 1001
(225)
the outside stiffness matrix is given by
19
dWWnjiS ji11)(
1))(
1(
(226)
where is the magnetic permeability n
is the normal vector is the volume and is the boundary surface of volume
Equation (220) and (221) form the FEM system with and a being the unknowns From this system only the outside stiffness matrix cannot be directly computed The calculation of this matrix will be made possible through the definition of the BEM system [7] The BEM system is used for the air and will not be shown in this report More information about it could be found in [7]
222 FEM model for temperature field
The steady state or transient temperature field on three dimensional geometries can also be solved by LS-DYNA Material properties may be temperature dependent and either isotopic or orthotropic A variety of time and temperature dependent boundary conditions can be specified including temperature flux convection and radiation The implementation of heat conduction into LS-DYNA is based on the work of Shapiro [16]
The differential equations of conduction of heat in a three-dimensional continuum is given by
Qkt
cijij
(227)
where )( txi is temperature )( ix is density )( ixcc is
the specific heat )( iijij xkk is thermal conductivity )( ixQQ is
internal heat generation rate per unit volume
The boundary conditions are
s on 1 (228)
20
ijij nk on 2 (229)
Initial conditions at 0t are given by
)(0 ix at 0tt (230)
where )(txx ii are coordinates as a function of time is prescribed
temperature on 1 and in is normal vector to 2
Equations (227-230) represent the strong form of a boundary value problem to be solved for the temperature field within the solid continuum [16]
The finite element method provides the following equations for the numerical solution of equations (227-230)
nnnnnnn HFHt
C
1 (231)
e
jie
eij
e
dcNNCC (232)
ejiji
T
e
eij
ee
dNNdNKNHH (233)
eigi
e
ei
ee
dNdqNFF (234)
where and are the parameters that are different when using different methods like Crank-Nicolson Galerkin and so on The parameter is taken to be in the interval [01] C H and F are the element stiffness load and boundary matrices respectively N is the element shape functions gq is the heat flow K is the thermal conductivity tensor
21
The boundary conditions for temperature flux convection and radiation are
)(
)(
)(
42
4112 TTF
n
T
TThn
T
qn
Tk
tzyxfT
w
sz
(235)
where T is the temperature k is the thermal conductivity n is the normal direction of the boundary szq
is the heat flux vector h is the convective
heat transfer coefficient wT is the surface temperature of the solid T is
the fluid temperature is the emissivity is the Stefan Boltzmann constant
223 FEM model for mechanical field
The equations that govern analyses of the behavior of a solid continuum are those of momentum conservation ie the equations of motion For an analysis of small deformation of a solid continuum these are (in tensor form) [17]
iijij ub (236)
where ij is the Cauchy stress tensor ib the body force vector per unit
volume the density and iu the displacement vector
To establish a weak form from the strong one we multiply (236) by an arbitrary velocity ie the test function iv and integrate over the region
By introducing two boundary conditions ii uu on u and ijijn on
where 0v on u the above differential equation in the weak form
[17] is given as
22
dvdbvduvdv iiiiiiijji (237)
To perform the FE discretization of the weak form (237) means to divide the continuum volume into sub-elements where the displacement field in every element is approximated by shape functions )(xNI and nodal
displacements )(tuiI that is summation of their products [17]
)()()( xNtutxu IiIi (238)
By approximating the test functions with the same shape functions (Galerkin method) we obtain
0)(
)()(
)(
)(
)(
)(
int)(
int
int
ee
e
e
dNbdNff
NdNMM
x
NBdBff
fuMfv
TTexte
ext
Te
j
IjI
Te
extT
(239)
which must hold for an arbitrary v and which puts the FE equation in order
intffuM ext (240)
For a linear material C the FE equation that emerges is
23
)(
)(e
dCBBKKfKuuM TTeext (241)
224 Numerical procedure
For the induction hardening process three different analyses have been combined in one numerical procedure mechanical thermal-metallurgical and electromagnetic (EM) computations They are solved fully transiently Boundary conditions and material properties beside one unique geometric model were required by each of them
What is necessary to mention is that some characteristics of the material are interdependent The electric conductivity for instance depends on the temperature In addition all thermal properties depend on the temperature [18] The variation of the properties with the temperature makes the system to be non-linear
There is a high coupling grade between thermal and EM equations because the electrical and magnetic properties laws depend on temperature When the initial temperature is known the eddy current value is calculated and then used to compute the heat generated by the Joule effect [5] At each time step the convergence is checked Until a steady state between the heat and the temperature field is reached the temperature value will be recalculated for each magnetic sub-step
EM solver can be coupled with the thermal and mechanical solvers in order to take full advantage of their capabilities [7] Both the thermal and the EM solver run with implicit time integration For mechanical solver there are two time integration methods of explicit and implicit type
Explicit and implicit methods are numerical schemes for obtaining numerical solutions of time-dependent ordinary and partial differential equations as is required in computer simulations of physical processes Explicit methods calculate the state of a system at a later time from the state of the system at the current time while implicit methods find a solution by solving an equation involving both the current state of the system and the later one [19] Here follows the difference between explicit and implicit methods
Implicit method
o More accurate
24
o It has large time step increment
o Convergence of each load step can be controlled to avoid error accumulation
o Iteration may not converge
Explicit method
o Less accurate
o It has small time step
o There is error accumulation and the error is difficult to estimate
o Iteration converges
However the implicit type has been governing the mechanical solver for the induction process in this thesis
Now let us go back to the couplings For the electromagnetic and structure interaction both the mechanical and the EM solver have distinct time steps By linear interpolation the EM fields are evaluated at the mechanical time step The two solvers will interact at each electromagnetic time step The EM solver will communicate the Lorentz force to the mechanical solver [7] resulting in an extra force in the mechanic equation
Lorentzext FfDt
Du (242)
where is total charge density is electrical conductivity extf is the
external force while LorentzF is the Lorentz force In turn the displacements
and deformations of the conductors are returned by the mechanical solver
When it comes to the thermal coupling at each electromagnetic time step the EM solver will communicate the extra Joule heating power term and the thermal solver will communicate the temperature
Figure 22 shows the interactions between the different solvers in LS-DYNA
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
9
Induction heating is the process of heating an electrically conducting object by electromagnetic induction where eddy currents are generated within the metal and resistance leads to Joule heating of the metal [6] This process is widely used in industrial operations due to its high efficiency precise control and more environmentally friendly properties [3] The induction heating has some characteristics compared to the traditional heating methods (such as furnace heating)
It has a precise depth of heating and the heating zone which is easier to control
It is easy to implement high power density fast heating high efficiency and low energy consumption
It is easy to control the high heating temperature
The conduction and infiltration of the heating temperature will be from the surface to the interior
There are no penetrating impurities since non-contact heating method is used
The burned part on the workpiece is smaller
The process is somewhat eco-friendly
It is easy to accomplish the automation of heating process
The quenching part of an induction hardening process is also an important part Cooling rates must be rapid in order to avoid softer undesirable structures such as pearlite and bainite Due to its importance the cooling portion of the induction hardening process deserves careful consideration particularly when specifying new induction equipment and processes Process parameters must be precisely controlled to assure consistent heat treatment results Excessive variation in these parameters will cause undesirable or inconsistent process results including problems with case depth hardness pattern and distortion [4] Water quench has been used for the problem in this thesis
12 Aim
Let us go to the main objective of this work Although the induction hardening process has many advantages the design of it which is usually based on experiments can be tiresome time-consuming and expensive
10
Luckily the fast development of the computer technology makes it possible to model the induction heat treatment process with numerical tools particularly with Finite Element Method (FEM) Nowadays a lot of engineers pay attention to this area
There are many FEM modeling works regarding either the heating or quenching heat treatment in the literature However numerical models of the integrated heat treatment ie both the induction heating and quenching are still gaining ground [5] Induction hardening is a complex physical process which has contributions from electrical magnetic thermal mechanical and metallurgical processes It is obvious that the complexity of the phenomena ndash including phase transformation and heat exchange makes the FEM analysis heavy and difficult
Different FEM softwares have been used for numerical studies of the induction hardening process In this study LS-DYNA has been used for simulations The electromagnetic field the eddy current and the temperature field have been calculated with the FEM and Boundary Element Method (BEM) In fact FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air thus no air mesh is needed The main study included
The mathematical description and the modeling of the induction heat treatment process
Solving the induction-hardening-modeling key technical issues
Simulating the induction hardening process with the existing commercial software LS-DYNA
Comparing the results of the simulation with the literature values and evaluating the softwarersquos capability
In short the aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The simulation results have been compared to literature results for evaluation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Here follows the model selected from a literature source [5] the induction heating and cooling of cylindrical workpiece The experimental setup is made of three parts the coil the bar and the cooling tool Figure 15
11
Figure 15 The experimental set-up
12
2 Induction and the corresponding numerical background
21 Induction process - Maxwell equations
The basic model is shown in Figure 21
Figure 21 Induction heating principle
The partial differential equations are used to solve the electromagnetic field distribution
In order to define the equations solved by the electromagnetic solver in LS-DYNA we start with the Maxwell equations [7]
t
BE
(21)
t
EjH
0 (22)
0 B
(23)
13
0
E
(24)
sjEj
(25)
HB
0 (26)
where E
is electric field B
is magnetic flux density t is time H
is
magnetic field intensity j
is current density 0 is permittivity of free
space is total charge density is electric conductivity sj
is source
current density and 0 is permeability of free space
The eddy current approximation used here implies a divergence-free current
density and no charge accumulation thus resulting in 00
t
E
and 0
Equations (22) and (24) in the eddy current approximation give
jH
(27)
0 E
(28)
0 j
(29)
The divergence condition given by equation (23) allows writing B
as
AB
(210)
where A
is the magnetic vector potential [8] Equation (21) then implies that the electric field is given by
t
AE
(211)
14
where is the electric scalar potential
Equation (210) leaves a mathematical degree of freedom to A
(if A
is
transformed to a given
A then Equation (210) remains valid) Therefore the introduction of a gauge ie a particular choice of the scalar and vector potentials is needed Gauge choosing denotes a mathematical procedure for coping with redundant degrees of freedom in field variables The gauge chosen here is the generalized Coulomb gauge
0 A
(212)
Equations (25) (29) (211) and (212) give
0
(213)
Equations (25) (27) (211) and (210) give
sjAt
A
1
(214)
Equation (213) and Equation (214) are the two equations constituting the system that will be solved where A
and are the two unknowns of the
problem [7]
211 Skin effect and skin depth
Skin effect is the tendency of an alternating electric current (AC) to become distributed within a conductor such that the current density is largest near the surface of the conductor and decreases with greater depths in the conductor [9]
Skin effect is associated with the current flowing mainly at the skin of the conductor at an average depth called the skin depth The skin depth is
15
defined as the depth at which the electromagnetic field in a conducting material has decreased to 037 of its value just outside the material which describes the electric and magnetic fields The formula for the skin depth is given by
ff rr
503
)2(
22
0
(215)
where is the skin depth f is the frequency is the average electrical
resistivity and r is the average relative permeability
212 Proximity effect
A changing magnetic field will influence the distribution of an electric current flowing within an electrical conductor by electromagnetic induction When an alternating current flows through an isolated conductor it creates an associated alternating magnetic field around it The alternating magnetic field induces eddy currents in adjacent conductors altering the overall distribution of current flowing through them ndash the distribution of current within the conductor will be constrained to smaller regions Subsequently the resistance is increased in those regions The resulting current crowding is termed the proximity effect Usually the current is concentrated in the areas of the conductor furthest away from nearby conductors carrying current in the same direction [10]
Thus since in our case the inductor is a coil the maximum current density will be at the inner side of the coil [3] So the inner side of the coil will be used to heat the workpiece which will get faster temperature increase and will be more efficient
22 Numerical basis of the induction process
All the physical phenomena encountered in engineering mechanics are modeled by differential equations Usually it is difficult to obtain accurate analytical solution of the differential equation However the numerical solution could be calculated but only when boundary conditions and initial
16
conditions under specific situations were given The following numerical methods are used to model the induction process in LS-DYNA
Finite Element Method
The FEM is today a powerful (often the most powerful) tool for numerical solution of any differential equation whether this arises from structural mechanics fluid mechanics thermodynamics biology ecology or any other field of science [11]
The finite element method is a numerical approach by which general differential equations can be solved in an approximate manner [12] A domain of interest is represented as an assembly of finite elements The FEM is useful for problems with complicated geometries loadings and material properties where analytical solutions cannot be obtained [13]
The main steps in the general FE formulation and solution of a physical problem are [11]
o Establish the strong form of the governing differential equation
o Transform this differential equation into the weak form
o Choose trial functions for the unknown function that is choose element type(s) and mesh the solution domain
o Choose weight functions and establish the system of algebraic equations for each element (element equations)
o Assemble these element systems into the global system of algebraic equations
o Introduce boundary conditions into the global system of algebraic equations
o Solve the system of algebraic equations and present the results or use them for further calculations
Boundary Element Method
The boundary element method (BEM) is a numerical computational method of solving linear partial differential equations which have been formulated as integral equations BEM attempts to use the given boundary conditions to fit only boundary values into the integral equation Once this is done the integral equation can then be used again to calculate numerically solution at any desired point in the interior of the solution domain The boundary
17
element method is often more efficient than other methods including FEM in terms of computational resources for problems where there is a small surfacevolume ratio Conceptually it works by constructing a mesh over the modeled surface However for many problems boundary element methods are significantly less suitable and efficient than volume-discretization methods [14]
In numerical computations of the problem in this thesis with LS-DYNA FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air
221 FEM model for electromagnetic field
In LS-DYNA equation (213) is projected on the 0W forms (0-forms are continuous scalar basis functions that have a well defined gradient the gradient of a 0-form being a 1- form) and equation (214) is projected on
the 1W
forms (1-forms are vector basis functions with continuous tangential components but discontinuous normal components) They have a well defined curl the curl of a 1-form being a 2-form) giving after integrating by part the following weak formulations [15]
00 dW
(216)
dWAndW
dWAdWt
A
11
11
)(
1
(217)
where d an element of volume and the surface of with n
outer normal to
The and A
decompositions on respectfully 0W and 1W
give
0iiw (218)
1iiwaA
(219)
18
When replacing and A
in equation (216) and (217) by (218) and (219) one gets
0)(0 S (220)
SaDaSt
aM
)()
1()( 0111
(221)
where
the stiffness matrix of the 0-forms is given by
dWWjiS ji000 ))((
(222)
the mass matrix of the 1-forms is given by
dWWjiM ji111 ))((
(223)
the stiffness matrix of the 1-forms is given by
dWWjiS ji )()(1
))(1
( 111
(224)
the derivative matrix of the 0-1-forms is given by
dWWjiD ji )())(( 1001
(225)
the outside stiffness matrix is given by
19
dWWnjiS ji11)(
1))(
1(
(226)
where is the magnetic permeability n
is the normal vector is the volume and is the boundary surface of volume
Equation (220) and (221) form the FEM system with and a being the unknowns From this system only the outside stiffness matrix cannot be directly computed The calculation of this matrix will be made possible through the definition of the BEM system [7] The BEM system is used for the air and will not be shown in this report More information about it could be found in [7]
222 FEM model for temperature field
The steady state or transient temperature field on three dimensional geometries can also be solved by LS-DYNA Material properties may be temperature dependent and either isotopic or orthotropic A variety of time and temperature dependent boundary conditions can be specified including temperature flux convection and radiation The implementation of heat conduction into LS-DYNA is based on the work of Shapiro [16]
The differential equations of conduction of heat in a three-dimensional continuum is given by
Qkt
cijij
(227)
where )( txi is temperature )( ix is density )( ixcc is
the specific heat )( iijij xkk is thermal conductivity )( ixQQ is
internal heat generation rate per unit volume
The boundary conditions are
s on 1 (228)
20
ijij nk on 2 (229)
Initial conditions at 0t are given by
)(0 ix at 0tt (230)
where )(txx ii are coordinates as a function of time is prescribed
temperature on 1 and in is normal vector to 2
Equations (227-230) represent the strong form of a boundary value problem to be solved for the temperature field within the solid continuum [16]
The finite element method provides the following equations for the numerical solution of equations (227-230)
nnnnnnn HFHt
C
1 (231)
e
jie
eij
e
dcNNCC (232)
ejiji
T
e
eij
ee
dNNdNKNHH (233)
eigi
e
ei
ee
dNdqNFF (234)
where and are the parameters that are different when using different methods like Crank-Nicolson Galerkin and so on The parameter is taken to be in the interval [01] C H and F are the element stiffness load and boundary matrices respectively N is the element shape functions gq is the heat flow K is the thermal conductivity tensor
21
The boundary conditions for temperature flux convection and radiation are
)(
)(
)(
42
4112 TTF
n
T
TThn
T
qn
Tk
tzyxfT
w
sz
(235)
where T is the temperature k is the thermal conductivity n is the normal direction of the boundary szq
is the heat flux vector h is the convective
heat transfer coefficient wT is the surface temperature of the solid T is
the fluid temperature is the emissivity is the Stefan Boltzmann constant
223 FEM model for mechanical field
The equations that govern analyses of the behavior of a solid continuum are those of momentum conservation ie the equations of motion For an analysis of small deformation of a solid continuum these are (in tensor form) [17]
iijij ub (236)
where ij is the Cauchy stress tensor ib the body force vector per unit
volume the density and iu the displacement vector
To establish a weak form from the strong one we multiply (236) by an arbitrary velocity ie the test function iv and integrate over the region
By introducing two boundary conditions ii uu on u and ijijn on
where 0v on u the above differential equation in the weak form
[17] is given as
22
dvdbvduvdv iiiiiiijji (237)
To perform the FE discretization of the weak form (237) means to divide the continuum volume into sub-elements where the displacement field in every element is approximated by shape functions )(xNI and nodal
displacements )(tuiI that is summation of their products [17]
)()()( xNtutxu IiIi (238)
By approximating the test functions with the same shape functions (Galerkin method) we obtain
0)(
)()(
)(
)(
)(
)(
int)(
int
int
ee
e
e
dNbdNff
NdNMM
x
NBdBff
fuMfv
TTexte
ext
Te
j
IjI
Te
extT
(239)
which must hold for an arbitrary v and which puts the FE equation in order
intffuM ext (240)
For a linear material C the FE equation that emerges is
23
)(
)(e
dCBBKKfKuuM TTeext (241)
224 Numerical procedure
For the induction hardening process three different analyses have been combined in one numerical procedure mechanical thermal-metallurgical and electromagnetic (EM) computations They are solved fully transiently Boundary conditions and material properties beside one unique geometric model were required by each of them
What is necessary to mention is that some characteristics of the material are interdependent The electric conductivity for instance depends on the temperature In addition all thermal properties depend on the temperature [18] The variation of the properties with the temperature makes the system to be non-linear
There is a high coupling grade between thermal and EM equations because the electrical and magnetic properties laws depend on temperature When the initial temperature is known the eddy current value is calculated and then used to compute the heat generated by the Joule effect [5] At each time step the convergence is checked Until a steady state between the heat and the temperature field is reached the temperature value will be recalculated for each magnetic sub-step
EM solver can be coupled with the thermal and mechanical solvers in order to take full advantage of their capabilities [7] Both the thermal and the EM solver run with implicit time integration For mechanical solver there are two time integration methods of explicit and implicit type
Explicit and implicit methods are numerical schemes for obtaining numerical solutions of time-dependent ordinary and partial differential equations as is required in computer simulations of physical processes Explicit methods calculate the state of a system at a later time from the state of the system at the current time while implicit methods find a solution by solving an equation involving both the current state of the system and the later one [19] Here follows the difference between explicit and implicit methods
Implicit method
o More accurate
24
o It has large time step increment
o Convergence of each load step can be controlled to avoid error accumulation
o Iteration may not converge
Explicit method
o Less accurate
o It has small time step
o There is error accumulation and the error is difficult to estimate
o Iteration converges
However the implicit type has been governing the mechanical solver for the induction process in this thesis
Now let us go back to the couplings For the electromagnetic and structure interaction both the mechanical and the EM solver have distinct time steps By linear interpolation the EM fields are evaluated at the mechanical time step The two solvers will interact at each electromagnetic time step The EM solver will communicate the Lorentz force to the mechanical solver [7] resulting in an extra force in the mechanic equation
Lorentzext FfDt
Du (242)
where is total charge density is electrical conductivity extf is the
external force while LorentzF is the Lorentz force In turn the displacements
and deformations of the conductors are returned by the mechanical solver
When it comes to the thermal coupling at each electromagnetic time step the EM solver will communicate the extra Joule heating power term and the thermal solver will communicate the temperature
Figure 22 shows the interactions between the different solvers in LS-DYNA
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
10
Luckily the fast development of the computer technology makes it possible to model the induction heat treatment process with numerical tools particularly with Finite Element Method (FEM) Nowadays a lot of engineers pay attention to this area
There are many FEM modeling works regarding either the heating or quenching heat treatment in the literature However numerical models of the integrated heat treatment ie both the induction heating and quenching are still gaining ground [5] Induction hardening is a complex physical process which has contributions from electrical magnetic thermal mechanical and metallurgical processes It is obvious that the complexity of the phenomena ndash including phase transformation and heat exchange makes the FEM analysis heavy and difficult
Different FEM softwares have been used for numerical studies of the induction hardening process In this study LS-DYNA has been used for simulations The electromagnetic field the eddy current and the temperature field have been calculated with the FEM and Boundary Element Method (BEM) In fact FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air thus no air mesh is needed The main study included
The mathematical description and the modeling of the induction heat treatment process
Solving the induction-hardening-modeling key technical issues
Simulating the induction hardening process with the existing commercial software LS-DYNA
Comparing the results of the simulation with the literature values and evaluating the softwarersquos capability
In short the aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The simulation results have been compared to literature results for evaluation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Here follows the model selected from a literature source [5] the induction heating and cooling of cylindrical workpiece The experimental setup is made of three parts the coil the bar and the cooling tool Figure 15
11
Figure 15 The experimental set-up
12
2 Induction and the corresponding numerical background
21 Induction process - Maxwell equations
The basic model is shown in Figure 21
Figure 21 Induction heating principle
The partial differential equations are used to solve the electromagnetic field distribution
In order to define the equations solved by the electromagnetic solver in LS-DYNA we start with the Maxwell equations [7]
t
BE
(21)
t
EjH
0 (22)
0 B
(23)
13
0
E
(24)
sjEj
(25)
HB
0 (26)
where E
is electric field B
is magnetic flux density t is time H
is
magnetic field intensity j
is current density 0 is permittivity of free
space is total charge density is electric conductivity sj
is source
current density and 0 is permeability of free space
The eddy current approximation used here implies a divergence-free current
density and no charge accumulation thus resulting in 00
t
E
and 0
Equations (22) and (24) in the eddy current approximation give
jH
(27)
0 E
(28)
0 j
(29)
The divergence condition given by equation (23) allows writing B
as
AB
(210)
where A
is the magnetic vector potential [8] Equation (21) then implies that the electric field is given by
t
AE
(211)
14
where is the electric scalar potential
Equation (210) leaves a mathematical degree of freedom to A
(if A
is
transformed to a given
A then Equation (210) remains valid) Therefore the introduction of a gauge ie a particular choice of the scalar and vector potentials is needed Gauge choosing denotes a mathematical procedure for coping with redundant degrees of freedom in field variables The gauge chosen here is the generalized Coulomb gauge
0 A
(212)
Equations (25) (29) (211) and (212) give
0
(213)
Equations (25) (27) (211) and (210) give
sjAt
A
1
(214)
Equation (213) and Equation (214) are the two equations constituting the system that will be solved where A
and are the two unknowns of the
problem [7]
211 Skin effect and skin depth
Skin effect is the tendency of an alternating electric current (AC) to become distributed within a conductor such that the current density is largest near the surface of the conductor and decreases with greater depths in the conductor [9]
Skin effect is associated with the current flowing mainly at the skin of the conductor at an average depth called the skin depth The skin depth is
15
defined as the depth at which the electromagnetic field in a conducting material has decreased to 037 of its value just outside the material which describes the electric and magnetic fields The formula for the skin depth is given by
ff rr
503
)2(
22
0
(215)
where is the skin depth f is the frequency is the average electrical
resistivity and r is the average relative permeability
212 Proximity effect
A changing magnetic field will influence the distribution of an electric current flowing within an electrical conductor by electromagnetic induction When an alternating current flows through an isolated conductor it creates an associated alternating magnetic field around it The alternating magnetic field induces eddy currents in adjacent conductors altering the overall distribution of current flowing through them ndash the distribution of current within the conductor will be constrained to smaller regions Subsequently the resistance is increased in those regions The resulting current crowding is termed the proximity effect Usually the current is concentrated in the areas of the conductor furthest away from nearby conductors carrying current in the same direction [10]
Thus since in our case the inductor is a coil the maximum current density will be at the inner side of the coil [3] So the inner side of the coil will be used to heat the workpiece which will get faster temperature increase and will be more efficient
22 Numerical basis of the induction process
All the physical phenomena encountered in engineering mechanics are modeled by differential equations Usually it is difficult to obtain accurate analytical solution of the differential equation However the numerical solution could be calculated but only when boundary conditions and initial
16
conditions under specific situations were given The following numerical methods are used to model the induction process in LS-DYNA
Finite Element Method
The FEM is today a powerful (often the most powerful) tool for numerical solution of any differential equation whether this arises from structural mechanics fluid mechanics thermodynamics biology ecology or any other field of science [11]
The finite element method is a numerical approach by which general differential equations can be solved in an approximate manner [12] A domain of interest is represented as an assembly of finite elements The FEM is useful for problems with complicated geometries loadings and material properties where analytical solutions cannot be obtained [13]
The main steps in the general FE formulation and solution of a physical problem are [11]
o Establish the strong form of the governing differential equation
o Transform this differential equation into the weak form
o Choose trial functions for the unknown function that is choose element type(s) and mesh the solution domain
o Choose weight functions and establish the system of algebraic equations for each element (element equations)
o Assemble these element systems into the global system of algebraic equations
o Introduce boundary conditions into the global system of algebraic equations
o Solve the system of algebraic equations and present the results or use them for further calculations
Boundary Element Method
The boundary element method (BEM) is a numerical computational method of solving linear partial differential equations which have been formulated as integral equations BEM attempts to use the given boundary conditions to fit only boundary values into the integral equation Once this is done the integral equation can then be used again to calculate numerically solution at any desired point in the interior of the solution domain The boundary
17
element method is often more efficient than other methods including FEM in terms of computational resources for problems where there is a small surfacevolume ratio Conceptually it works by constructing a mesh over the modeled surface However for many problems boundary element methods are significantly less suitable and efficient than volume-discretization methods [14]
In numerical computations of the problem in this thesis with LS-DYNA FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air
221 FEM model for electromagnetic field
In LS-DYNA equation (213) is projected on the 0W forms (0-forms are continuous scalar basis functions that have a well defined gradient the gradient of a 0-form being a 1- form) and equation (214) is projected on
the 1W
forms (1-forms are vector basis functions with continuous tangential components but discontinuous normal components) They have a well defined curl the curl of a 1-form being a 2-form) giving after integrating by part the following weak formulations [15]
00 dW
(216)
dWAndW
dWAdWt
A
11
11
)(
1
(217)
where d an element of volume and the surface of with n
outer normal to
The and A
decompositions on respectfully 0W and 1W
give
0iiw (218)
1iiwaA
(219)
18
When replacing and A
in equation (216) and (217) by (218) and (219) one gets
0)(0 S (220)
SaDaSt
aM
)()
1()( 0111
(221)
where
the stiffness matrix of the 0-forms is given by
dWWjiS ji000 ))((
(222)
the mass matrix of the 1-forms is given by
dWWjiM ji111 ))((
(223)
the stiffness matrix of the 1-forms is given by
dWWjiS ji )()(1
))(1
( 111
(224)
the derivative matrix of the 0-1-forms is given by
dWWjiD ji )())(( 1001
(225)
the outside stiffness matrix is given by
19
dWWnjiS ji11)(
1))(
1(
(226)
where is the magnetic permeability n
is the normal vector is the volume and is the boundary surface of volume
Equation (220) and (221) form the FEM system with and a being the unknowns From this system only the outside stiffness matrix cannot be directly computed The calculation of this matrix will be made possible through the definition of the BEM system [7] The BEM system is used for the air and will not be shown in this report More information about it could be found in [7]
222 FEM model for temperature field
The steady state or transient temperature field on three dimensional geometries can also be solved by LS-DYNA Material properties may be temperature dependent and either isotopic or orthotropic A variety of time and temperature dependent boundary conditions can be specified including temperature flux convection and radiation The implementation of heat conduction into LS-DYNA is based on the work of Shapiro [16]
The differential equations of conduction of heat in a three-dimensional continuum is given by
Qkt
cijij
(227)
where )( txi is temperature )( ix is density )( ixcc is
the specific heat )( iijij xkk is thermal conductivity )( ixQQ is
internal heat generation rate per unit volume
The boundary conditions are
s on 1 (228)
20
ijij nk on 2 (229)
Initial conditions at 0t are given by
)(0 ix at 0tt (230)
where )(txx ii are coordinates as a function of time is prescribed
temperature on 1 and in is normal vector to 2
Equations (227-230) represent the strong form of a boundary value problem to be solved for the temperature field within the solid continuum [16]
The finite element method provides the following equations for the numerical solution of equations (227-230)
nnnnnnn HFHt
C
1 (231)
e
jie
eij
e
dcNNCC (232)
ejiji
T
e
eij
ee
dNNdNKNHH (233)
eigi
e
ei
ee
dNdqNFF (234)
where and are the parameters that are different when using different methods like Crank-Nicolson Galerkin and so on The parameter is taken to be in the interval [01] C H and F are the element stiffness load and boundary matrices respectively N is the element shape functions gq is the heat flow K is the thermal conductivity tensor
21
The boundary conditions for temperature flux convection and radiation are
)(
)(
)(
42
4112 TTF
n
T
TThn
T
qn
Tk
tzyxfT
w
sz
(235)
where T is the temperature k is the thermal conductivity n is the normal direction of the boundary szq
is the heat flux vector h is the convective
heat transfer coefficient wT is the surface temperature of the solid T is
the fluid temperature is the emissivity is the Stefan Boltzmann constant
223 FEM model for mechanical field
The equations that govern analyses of the behavior of a solid continuum are those of momentum conservation ie the equations of motion For an analysis of small deformation of a solid continuum these are (in tensor form) [17]
iijij ub (236)
where ij is the Cauchy stress tensor ib the body force vector per unit
volume the density and iu the displacement vector
To establish a weak form from the strong one we multiply (236) by an arbitrary velocity ie the test function iv and integrate over the region
By introducing two boundary conditions ii uu on u and ijijn on
where 0v on u the above differential equation in the weak form
[17] is given as
22
dvdbvduvdv iiiiiiijji (237)
To perform the FE discretization of the weak form (237) means to divide the continuum volume into sub-elements where the displacement field in every element is approximated by shape functions )(xNI and nodal
displacements )(tuiI that is summation of their products [17]
)()()( xNtutxu IiIi (238)
By approximating the test functions with the same shape functions (Galerkin method) we obtain
0)(
)()(
)(
)(
)(
)(
int)(
int
int
ee
e
e
dNbdNff
NdNMM
x
NBdBff
fuMfv
TTexte
ext
Te
j
IjI
Te
extT
(239)
which must hold for an arbitrary v and which puts the FE equation in order
intffuM ext (240)
For a linear material C the FE equation that emerges is
23
)(
)(e
dCBBKKfKuuM TTeext (241)
224 Numerical procedure
For the induction hardening process three different analyses have been combined in one numerical procedure mechanical thermal-metallurgical and electromagnetic (EM) computations They are solved fully transiently Boundary conditions and material properties beside one unique geometric model were required by each of them
What is necessary to mention is that some characteristics of the material are interdependent The electric conductivity for instance depends on the temperature In addition all thermal properties depend on the temperature [18] The variation of the properties with the temperature makes the system to be non-linear
There is a high coupling grade between thermal and EM equations because the electrical and magnetic properties laws depend on temperature When the initial temperature is known the eddy current value is calculated and then used to compute the heat generated by the Joule effect [5] At each time step the convergence is checked Until a steady state between the heat and the temperature field is reached the temperature value will be recalculated for each magnetic sub-step
EM solver can be coupled with the thermal and mechanical solvers in order to take full advantage of their capabilities [7] Both the thermal and the EM solver run with implicit time integration For mechanical solver there are two time integration methods of explicit and implicit type
Explicit and implicit methods are numerical schemes for obtaining numerical solutions of time-dependent ordinary and partial differential equations as is required in computer simulations of physical processes Explicit methods calculate the state of a system at a later time from the state of the system at the current time while implicit methods find a solution by solving an equation involving both the current state of the system and the later one [19] Here follows the difference between explicit and implicit methods
Implicit method
o More accurate
24
o It has large time step increment
o Convergence of each load step can be controlled to avoid error accumulation
o Iteration may not converge
Explicit method
o Less accurate
o It has small time step
o There is error accumulation and the error is difficult to estimate
o Iteration converges
However the implicit type has been governing the mechanical solver for the induction process in this thesis
Now let us go back to the couplings For the electromagnetic and structure interaction both the mechanical and the EM solver have distinct time steps By linear interpolation the EM fields are evaluated at the mechanical time step The two solvers will interact at each electromagnetic time step The EM solver will communicate the Lorentz force to the mechanical solver [7] resulting in an extra force in the mechanic equation
Lorentzext FfDt
Du (242)
where is total charge density is electrical conductivity extf is the
external force while LorentzF is the Lorentz force In turn the displacements
and deformations of the conductors are returned by the mechanical solver
When it comes to the thermal coupling at each electromagnetic time step the EM solver will communicate the extra Joule heating power term and the thermal solver will communicate the temperature
Figure 22 shows the interactions between the different solvers in LS-DYNA
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
11
Figure 15 The experimental set-up
12
2 Induction and the corresponding numerical background
21 Induction process - Maxwell equations
The basic model is shown in Figure 21
Figure 21 Induction heating principle
The partial differential equations are used to solve the electromagnetic field distribution
In order to define the equations solved by the electromagnetic solver in LS-DYNA we start with the Maxwell equations [7]
t
BE
(21)
t
EjH
0 (22)
0 B
(23)
13
0
E
(24)
sjEj
(25)
HB
0 (26)
where E
is electric field B
is magnetic flux density t is time H
is
magnetic field intensity j
is current density 0 is permittivity of free
space is total charge density is electric conductivity sj
is source
current density and 0 is permeability of free space
The eddy current approximation used here implies a divergence-free current
density and no charge accumulation thus resulting in 00
t
E
and 0
Equations (22) and (24) in the eddy current approximation give
jH
(27)
0 E
(28)
0 j
(29)
The divergence condition given by equation (23) allows writing B
as
AB
(210)
where A
is the magnetic vector potential [8] Equation (21) then implies that the electric field is given by
t
AE
(211)
14
where is the electric scalar potential
Equation (210) leaves a mathematical degree of freedom to A
(if A
is
transformed to a given
A then Equation (210) remains valid) Therefore the introduction of a gauge ie a particular choice of the scalar and vector potentials is needed Gauge choosing denotes a mathematical procedure for coping with redundant degrees of freedom in field variables The gauge chosen here is the generalized Coulomb gauge
0 A
(212)
Equations (25) (29) (211) and (212) give
0
(213)
Equations (25) (27) (211) and (210) give
sjAt
A
1
(214)
Equation (213) and Equation (214) are the two equations constituting the system that will be solved where A
and are the two unknowns of the
problem [7]
211 Skin effect and skin depth
Skin effect is the tendency of an alternating electric current (AC) to become distributed within a conductor such that the current density is largest near the surface of the conductor and decreases with greater depths in the conductor [9]
Skin effect is associated with the current flowing mainly at the skin of the conductor at an average depth called the skin depth The skin depth is
15
defined as the depth at which the electromagnetic field in a conducting material has decreased to 037 of its value just outside the material which describes the electric and magnetic fields The formula for the skin depth is given by
ff rr
503
)2(
22
0
(215)
where is the skin depth f is the frequency is the average electrical
resistivity and r is the average relative permeability
212 Proximity effect
A changing magnetic field will influence the distribution of an electric current flowing within an electrical conductor by electromagnetic induction When an alternating current flows through an isolated conductor it creates an associated alternating magnetic field around it The alternating magnetic field induces eddy currents in adjacent conductors altering the overall distribution of current flowing through them ndash the distribution of current within the conductor will be constrained to smaller regions Subsequently the resistance is increased in those regions The resulting current crowding is termed the proximity effect Usually the current is concentrated in the areas of the conductor furthest away from nearby conductors carrying current in the same direction [10]
Thus since in our case the inductor is a coil the maximum current density will be at the inner side of the coil [3] So the inner side of the coil will be used to heat the workpiece which will get faster temperature increase and will be more efficient
22 Numerical basis of the induction process
All the physical phenomena encountered in engineering mechanics are modeled by differential equations Usually it is difficult to obtain accurate analytical solution of the differential equation However the numerical solution could be calculated but only when boundary conditions and initial
16
conditions under specific situations were given The following numerical methods are used to model the induction process in LS-DYNA
Finite Element Method
The FEM is today a powerful (often the most powerful) tool for numerical solution of any differential equation whether this arises from structural mechanics fluid mechanics thermodynamics biology ecology or any other field of science [11]
The finite element method is a numerical approach by which general differential equations can be solved in an approximate manner [12] A domain of interest is represented as an assembly of finite elements The FEM is useful for problems with complicated geometries loadings and material properties where analytical solutions cannot be obtained [13]
The main steps in the general FE formulation and solution of a physical problem are [11]
o Establish the strong form of the governing differential equation
o Transform this differential equation into the weak form
o Choose trial functions for the unknown function that is choose element type(s) and mesh the solution domain
o Choose weight functions and establish the system of algebraic equations for each element (element equations)
o Assemble these element systems into the global system of algebraic equations
o Introduce boundary conditions into the global system of algebraic equations
o Solve the system of algebraic equations and present the results or use them for further calculations
Boundary Element Method
The boundary element method (BEM) is a numerical computational method of solving linear partial differential equations which have been formulated as integral equations BEM attempts to use the given boundary conditions to fit only boundary values into the integral equation Once this is done the integral equation can then be used again to calculate numerically solution at any desired point in the interior of the solution domain The boundary
17
element method is often more efficient than other methods including FEM in terms of computational resources for problems where there is a small surfacevolume ratio Conceptually it works by constructing a mesh over the modeled surface However for many problems boundary element methods are significantly less suitable and efficient than volume-discretization methods [14]
In numerical computations of the problem in this thesis with LS-DYNA FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air
221 FEM model for electromagnetic field
In LS-DYNA equation (213) is projected on the 0W forms (0-forms are continuous scalar basis functions that have a well defined gradient the gradient of a 0-form being a 1- form) and equation (214) is projected on
the 1W
forms (1-forms are vector basis functions with continuous tangential components but discontinuous normal components) They have a well defined curl the curl of a 1-form being a 2-form) giving after integrating by part the following weak formulations [15]
00 dW
(216)
dWAndW
dWAdWt
A
11
11
)(
1
(217)
where d an element of volume and the surface of with n
outer normal to
The and A
decompositions on respectfully 0W and 1W
give
0iiw (218)
1iiwaA
(219)
18
When replacing and A
in equation (216) and (217) by (218) and (219) one gets
0)(0 S (220)
SaDaSt
aM
)()
1()( 0111
(221)
where
the stiffness matrix of the 0-forms is given by
dWWjiS ji000 ))((
(222)
the mass matrix of the 1-forms is given by
dWWjiM ji111 ))((
(223)
the stiffness matrix of the 1-forms is given by
dWWjiS ji )()(1
))(1
( 111
(224)
the derivative matrix of the 0-1-forms is given by
dWWjiD ji )())(( 1001
(225)
the outside stiffness matrix is given by
19
dWWnjiS ji11)(
1))(
1(
(226)
where is the magnetic permeability n
is the normal vector is the volume and is the boundary surface of volume
Equation (220) and (221) form the FEM system with and a being the unknowns From this system only the outside stiffness matrix cannot be directly computed The calculation of this matrix will be made possible through the definition of the BEM system [7] The BEM system is used for the air and will not be shown in this report More information about it could be found in [7]
222 FEM model for temperature field
The steady state or transient temperature field on three dimensional geometries can also be solved by LS-DYNA Material properties may be temperature dependent and either isotopic or orthotropic A variety of time and temperature dependent boundary conditions can be specified including temperature flux convection and radiation The implementation of heat conduction into LS-DYNA is based on the work of Shapiro [16]
The differential equations of conduction of heat in a three-dimensional continuum is given by
Qkt
cijij
(227)
where )( txi is temperature )( ix is density )( ixcc is
the specific heat )( iijij xkk is thermal conductivity )( ixQQ is
internal heat generation rate per unit volume
The boundary conditions are
s on 1 (228)
20
ijij nk on 2 (229)
Initial conditions at 0t are given by
)(0 ix at 0tt (230)
where )(txx ii are coordinates as a function of time is prescribed
temperature on 1 and in is normal vector to 2
Equations (227-230) represent the strong form of a boundary value problem to be solved for the temperature field within the solid continuum [16]
The finite element method provides the following equations for the numerical solution of equations (227-230)
nnnnnnn HFHt
C
1 (231)
e
jie
eij
e
dcNNCC (232)
ejiji
T
e
eij
ee
dNNdNKNHH (233)
eigi
e
ei
ee
dNdqNFF (234)
where and are the parameters that are different when using different methods like Crank-Nicolson Galerkin and so on The parameter is taken to be in the interval [01] C H and F are the element stiffness load and boundary matrices respectively N is the element shape functions gq is the heat flow K is the thermal conductivity tensor
21
The boundary conditions for temperature flux convection and radiation are
)(
)(
)(
42
4112 TTF
n
T
TThn
T
qn
Tk
tzyxfT
w
sz
(235)
where T is the temperature k is the thermal conductivity n is the normal direction of the boundary szq
is the heat flux vector h is the convective
heat transfer coefficient wT is the surface temperature of the solid T is
the fluid temperature is the emissivity is the Stefan Boltzmann constant
223 FEM model for mechanical field
The equations that govern analyses of the behavior of a solid continuum are those of momentum conservation ie the equations of motion For an analysis of small deformation of a solid continuum these are (in tensor form) [17]
iijij ub (236)
where ij is the Cauchy stress tensor ib the body force vector per unit
volume the density and iu the displacement vector
To establish a weak form from the strong one we multiply (236) by an arbitrary velocity ie the test function iv and integrate over the region
By introducing two boundary conditions ii uu on u and ijijn on
where 0v on u the above differential equation in the weak form
[17] is given as
22
dvdbvduvdv iiiiiiijji (237)
To perform the FE discretization of the weak form (237) means to divide the continuum volume into sub-elements where the displacement field in every element is approximated by shape functions )(xNI and nodal
displacements )(tuiI that is summation of their products [17]
)()()( xNtutxu IiIi (238)
By approximating the test functions with the same shape functions (Galerkin method) we obtain
0)(
)()(
)(
)(
)(
)(
int)(
int
int
ee
e
e
dNbdNff
NdNMM
x
NBdBff
fuMfv
TTexte
ext
Te
j
IjI
Te
extT
(239)
which must hold for an arbitrary v and which puts the FE equation in order
intffuM ext (240)
For a linear material C the FE equation that emerges is
23
)(
)(e
dCBBKKfKuuM TTeext (241)
224 Numerical procedure
For the induction hardening process three different analyses have been combined in one numerical procedure mechanical thermal-metallurgical and electromagnetic (EM) computations They are solved fully transiently Boundary conditions and material properties beside one unique geometric model were required by each of them
What is necessary to mention is that some characteristics of the material are interdependent The electric conductivity for instance depends on the temperature In addition all thermal properties depend on the temperature [18] The variation of the properties with the temperature makes the system to be non-linear
There is a high coupling grade between thermal and EM equations because the electrical and magnetic properties laws depend on temperature When the initial temperature is known the eddy current value is calculated and then used to compute the heat generated by the Joule effect [5] At each time step the convergence is checked Until a steady state between the heat and the temperature field is reached the temperature value will be recalculated for each magnetic sub-step
EM solver can be coupled with the thermal and mechanical solvers in order to take full advantage of their capabilities [7] Both the thermal and the EM solver run with implicit time integration For mechanical solver there are two time integration methods of explicit and implicit type
Explicit and implicit methods are numerical schemes for obtaining numerical solutions of time-dependent ordinary and partial differential equations as is required in computer simulations of physical processes Explicit methods calculate the state of a system at a later time from the state of the system at the current time while implicit methods find a solution by solving an equation involving both the current state of the system and the later one [19] Here follows the difference between explicit and implicit methods
Implicit method
o More accurate
24
o It has large time step increment
o Convergence of each load step can be controlled to avoid error accumulation
o Iteration may not converge
Explicit method
o Less accurate
o It has small time step
o There is error accumulation and the error is difficult to estimate
o Iteration converges
However the implicit type has been governing the mechanical solver for the induction process in this thesis
Now let us go back to the couplings For the electromagnetic and structure interaction both the mechanical and the EM solver have distinct time steps By linear interpolation the EM fields are evaluated at the mechanical time step The two solvers will interact at each electromagnetic time step The EM solver will communicate the Lorentz force to the mechanical solver [7] resulting in an extra force in the mechanic equation
Lorentzext FfDt
Du (242)
where is total charge density is electrical conductivity extf is the
external force while LorentzF is the Lorentz force In turn the displacements
and deformations of the conductors are returned by the mechanical solver
When it comes to the thermal coupling at each electromagnetic time step the EM solver will communicate the extra Joule heating power term and the thermal solver will communicate the temperature
Figure 22 shows the interactions between the different solvers in LS-DYNA
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
12
2 Induction and the corresponding numerical background
21 Induction process - Maxwell equations
The basic model is shown in Figure 21
Figure 21 Induction heating principle
The partial differential equations are used to solve the electromagnetic field distribution
In order to define the equations solved by the electromagnetic solver in LS-DYNA we start with the Maxwell equations [7]
t
BE
(21)
t
EjH
0 (22)
0 B
(23)
13
0
E
(24)
sjEj
(25)
HB
0 (26)
where E
is electric field B
is magnetic flux density t is time H
is
magnetic field intensity j
is current density 0 is permittivity of free
space is total charge density is electric conductivity sj
is source
current density and 0 is permeability of free space
The eddy current approximation used here implies a divergence-free current
density and no charge accumulation thus resulting in 00
t
E
and 0
Equations (22) and (24) in the eddy current approximation give
jH
(27)
0 E
(28)
0 j
(29)
The divergence condition given by equation (23) allows writing B
as
AB
(210)
where A
is the magnetic vector potential [8] Equation (21) then implies that the electric field is given by
t
AE
(211)
14
where is the electric scalar potential
Equation (210) leaves a mathematical degree of freedom to A
(if A
is
transformed to a given
A then Equation (210) remains valid) Therefore the introduction of a gauge ie a particular choice of the scalar and vector potentials is needed Gauge choosing denotes a mathematical procedure for coping with redundant degrees of freedom in field variables The gauge chosen here is the generalized Coulomb gauge
0 A
(212)
Equations (25) (29) (211) and (212) give
0
(213)
Equations (25) (27) (211) and (210) give
sjAt
A
1
(214)
Equation (213) and Equation (214) are the two equations constituting the system that will be solved where A
and are the two unknowns of the
problem [7]
211 Skin effect and skin depth
Skin effect is the tendency of an alternating electric current (AC) to become distributed within a conductor such that the current density is largest near the surface of the conductor and decreases with greater depths in the conductor [9]
Skin effect is associated with the current flowing mainly at the skin of the conductor at an average depth called the skin depth The skin depth is
15
defined as the depth at which the electromagnetic field in a conducting material has decreased to 037 of its value just outside the material which describes the electric and magnetic fields The formula for the skin depth is given by
ff rr
503
)2(
22
0
(215)
where is the skin depth f is the frequency is the average electrical
resistivity and r is the average relative permeability
212 Proximity effect
A changing magnetic field will influence the distribution of an electric current flowing within an electrical conductor by electromagnetic induction When an alternating current flows through an isolated conductor it creates an associated alternating magnetic field around it The alternating magnetic field induces eddy currents in adjacent conductors altering the overall distribution of current flowing through them ndash the distribution of current within the conductor will be constrained to smaller regions Subsequently the resistance is increased in those regions The resulting current crowding is termed the proximity effect Usually the current is concentrated in the areas of the conductor furthest away from nearby conductors carrying current in the same direction [10]
Thus since in our case the inductor is a coil the maximum current density will be at the inner side of the coil [3] So the inner side of the coil will be used to heat the workpiece which will get faster temperature increase and will be more efficient
22 Numerical basis of the induction process
All the physical phenomena encountered in engineering mechanics are modeled by differential equations Usually it is difficult to obtain accurate analytical solution of the differential equation However the numerical solution could be calculated but only when boundary conditions and initial
16
conditions under specific situations were given The following numerical methods are used to model the induction process in LS-DYNA
Finite Element Method
The FEM is today a powerful (often the most powerful) tool for numerical solution of any differential equation whether this arises from structural mechanics fluid mechanics thermodynamics biology ecology or any other field of science [11]
The finite element method is a numerical approach by which general differential equations can be solved in an approximate manner [12] A domain of interest is represented as an assembly of finite elements The FEM is useful for problems with complicated geometries loadings and material properties where analytical solutions cannot be obtained [13]
The main steps in the general FE formulation and solution of a physical problem are [11]
o Establish the strong form of the governing differential equation
o Transform this differential equation into the weak form
o Choose trial functions for the unknown function that is choose element type(s) and mesh the solution domain
o Choose weight functions and establish the system of algebraic equations for each element (element equations)
o Assemble these element systems into the global system of algebraic equations
o Introduce boundary conditions into the global system of algebraic equations
o Solve the system of algebraic equations and present the results or use them for further calculations
Boundary Element Method
The boundary element method (BEM) is a numerical computational method of solving linear partial differential equations which have been formulated as integral equations BEM attempts to use the given boundary conditions to fit only boundary values into the integral equation Once this is done the integral equation can then be used again to calculate numerically solution at any desired point in the interior of the solution domain The boundary
17
element method is often more efficient than other methods including FEM in terms of computational resources for problems where there is a small surfacevolume ratio Conceptually it works by constructing a mesh over the modeled surface However for many problems boundary element methods are significantly less suitable and efficient than volume-discretization methods [14]
In numerical computations of the problem in this thesis with LS-DYNA FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air
221 FEM model for electromagnetic field
In LS-DYNA equation (213) is projected on the 0W forms (0-forms are continuous scalar basis functions that have a well defined gradient the gradient of a 0-form being a 1- form) and equation (214) is projected on
the 1W
forms (1-forms are vector basis functions with continuous tangential components but discontinuous normal components) They have a well defined curl the curl of a 1-form being a 2-form) giving after integrating by part the following weak formulations [15]
00 dW
(216)
dWAndW
dWAdWt
A
11
11
)(
1
(217)
where d an element of volume and the surface of with n
outer normal to
The and A
decompositions on respectfully 0W and 1W
give
0iiw (218)
1iiwaA
(219)
18
When replacing and A
in equation (216) and (217) by (218) and (219) one gets
0)(0 S (220)
SaDaSt
aM
)()
1()( 0111
(221)
where
the stiffness matrix of the 0-forms is given by
dWWjiS ji000 ))((
(222)
the mass matrix of the 1-forms is given by
dWWjiM ji111 ))((
(223)
the stiffness matrix of the 1-forms is given by
dWWjiS ji )()(1
))(1
( 111
(224)
the derivative matrix of the 0-1-forms is given by
dWWjiD ji )())(( 1001
(225)
the outside stiffness matrix is given by
19
dWWnjiS ji11)(
1))(
1(
(226)
where is the magnetic permeability n
is the normal vector is the volume and is the boundary surface of volume
Equation (220) and (221) form the FEM system with and a being the unknowns From this system only the outside stiffness matrix cannot be directly computed The calculation of this matrix will be made possible through the definition of the BEM system [7] The BEM system is used for the air and will not be shown in this report More information about it could be found in [7]
222 FEM model for temperature field
The steady state or transient temperature field on three dimensional geometries can also be solved by LS-DYNA Material properties may be temperature dependent and either isotopic or orthotropic A variety of time and temperature dependent boundary conditions can be specified including temperature flux convection and radiation The implementation of heat conduction into LS-DYNA is based on the work of Shapiro [16]
The differential equations of conduction of heat in a three-dimensional continuum is given by
Qkt
cijij
(227)
where )( txi is temperature )( ix is density )( ixcc is
the specific heat )( iijij xkk is thermal conductivity )( ixQQ is
internal heat generation rate per unit volume
The boundary conditions are
s on 1 (228)
20
ijij nk on 2 (229)
Initial conditions at 0t are given by
)(0 ix at 0tt (230)
where )(txx ii are coordinates as a function of time is prescribed
temperature on 1 and in is normal vector to 2
Equations (227-230) represent the strong form of a boundary value problem to be solved for the temperature field within the solid continuum [16]
The finite element method provides the following equations for the numerical solution of equations (227-230)
nnnnnnn HFHt
C
1 (231)
e
jie
eij
e
dcNNCC (232)
ejiji
T
e
eij
ee
dNNdNKNHH (233)
eigi
e
ei
ee
dNdqNFF (234)
where and are the parameters that are different when using different methods like Crank-Nicolson Galerkin and so on The parameter is taken to be in the interval [01] C H and F are the element stiffness load and boundary matrices respectively N is the element shape functions gq is the heat flow K is the thermal conductivity tensor
21
The boundary conditions for temperature flux convection and radiation are
)(
)(
)(
42
4112 TTF
n
T
TThn
T
qn
Tk
tzyxfT
w
sz
(235)
where T is the temperature k is the thermal conductivity n is the normal direction of the boundary szq
is the heat flux vector h is the convective
heat transfer coefficient wT is the surface temperature of the solid T is
the fluid temperature is the emissivity is the Stefan Boltzmann constant
223 FEM model for mechanical field
The equations that govern analyses of the behavior of a solid continuum are those of momentum conservation ie the equations of motion For an analysis of small deformation of a solid continuum these are (in tensor form) [17]
iijij ub (236)
where ij is the Cauchy stress tensor ib the body force vector per unit
volume the density and iu the displacement vector
To establish a weak form from the strong one we multiply (236) by an arbitrary velocity ie the test function iv and integrate over the region
By introducing two boundary conditions ii uu on u and ijijn on
where 0v on u the above differential equation in the weak form
[17] is given as
22
dvdbvduvdv iiiiiiijji (237)
To perform the FE discretization of the weak form (237) means to divide the continuum volume into sub-elements where the displacement field in every element is approximated by shape functions )(xNI and nodal
displacements )(tuiI that is summation of their products [17]
)()()( xNtutxu IiIi (238)
By approximating the test functions with the same shape functions (Galerkin method) we obtain
0)(
)()(
)(
)(
)(
)(
int)(
int
int
ee
e
e
dNbdNff
NdNMM
x
NBdBff
fuMfv
TTexte
ext
Te
j
IjI
Te
extT
(239)
which must hold for an arbitrary v and which puts the FE equation in order
intffuM ext (240)
For a linear material C the FE equation that emerges is
23
)(
)(e
dCBBKKfKuuM TTeext (241)
224 Numerical procedure
For the induction hardening process three different analyses have been combined in one numerical procedure mechanical thermal-metallurgical and electromagnetic (EM) computations They are solved fully transiently Boundary conditions and material properties beside one unique geometric model were required by each of them
What is necessary to mention is that some characteristics of the material are interdependent The electric conductivity for instance depends on the temperature In addition all thermal properties depend on the temperature [18] The variation of the properties with the temperature makes the system to be non-linear
There is a high coupling grade between thermal and EM equations because the electrical and magnetic properties laws depend on temperature When the initial temperature is known the eddy current value is calculated and then used to compute the heat generated by the Joule effect [5] At each time step the convergence is checked Until a steady state between the heat and the temperature field is reached the temperature value will be recalculated for each magnetic sub-step
EM solver can be coupled with the thermal and mechanical solvers in order to take full advantage of their capabilities [7] Both the thermal and the EM solver run with implicit time integration For mechanical solver there are two time integration methods of explicit and implicit type
Explicit and implicit methods are numerical schemes for obtaining numerical solutions of time-dependent ordinary and partial differential equations as is required in computer simulations of physical processes Explicit methods calculate the state of a system at a later time from the state of the system at the current time while implicit methods find a solution by solving an equation involving both the current state of the system and the later one [19] Here follows the difference between explicit and implicit methods
Implicit method
o More accurate
24
o It has large time step increment
o Convergence of each load step can be controlled to avoid error accumulation
o Iteration may not converge
Explicit method
o Less accurate
o It has small time step
o There is error accumulation and the error is difficult to estimate
o Iteration converges
However the implicit type has been governing the mechanical solver for the induction process in this thesis
Now let us go back to the couplings For the electromagnetic and structure interaction both the mechanical and the EM solver have distinct time steps By linear interpolation the EM fields are evaluated at the mechanical time step The two solvers will interact at each electromagnetic time step The EM solver will communicate the Lorentz force to the mechanical solver [7] resulting in an extra force in the mechanic equation
Lorentzext FfDt
Du (242)
where is total charge density is electrical conductivity extf is the
external force while LorentzF is the Lorentz force In turn the displacements
and deformations of the conductors are returned by the mechanical solver
When it comes to the thermal coupling at each electromagnetic time step the EM solver will communicate the extra Joule heating power term and the thermal solver will communicate the temperature
Figure 22 shows the interactions between the different solvers in LS-DYNA
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
13
0
E
(24)
sjEj
(25)
HB
0 (26)
where E
is electric field B
is magnetic flux density t is time H
is
magnetic field intensity j
is current density 0 is permittivity of free
space is total charge density is electric conductivity sj
is source
current density and 0 is permeability of free space
The eddy current approximation used here implies a divergence-free current
density and no charge accumulation thus resulting in 00
t
E
and 0
Equations (22) and (24) in the eddy current approximation give
jH
(27)
0 E
(28)
0 j
(29)
The divergence condition given by equation (23) allows writing B
as
AB
(210)
where A
is the magnetic vector potential [8] Equation (21) then implies that the electric field is given by
t
AE
(211)
14
where is the electric scalar potential
Equation (210) leaves a mathematical degree of freedom to A
(if A
is
transformed to a given
A then Equation (210) remains valid) Therefore the introduction of a gauge ie a particular choice of the scalar and vector potentials is needed Gauge choosing denotes a mathematical procedure for coping with redundant degrees of freedom in field variables The gauge chosen here is the generalized Coulomb gauge
0 A
(212)
Equations (25) (29) (211) and (212) give
0
(213)
Equations (25) (27) (211) and (210) give
sjAt
A
1
(214)
Equation (213) and Equation (214) are the two equations constituting the system that will be solved where A
and are the two unknowns of the
problem [7]
211 Skin effect and skin depth
Skin effect is the tendency of an alternating electric current (AC) to become distributed within a conductor such that the current density is largest near the surface of the conductor and decreases with greater depths in the conductor [9]
Skin effect is associated with the current flowing mainly at the skin of the conductor at an average depth called the skin depth The skin depth is
15
defined as the depth at which the electromagnetic field in a conducting material has decreased to 037 of its value just outside the material which describes the electric and magnetic fields The formula for the skin depth is given by
ff rr
503
)2(
22
0
(215)
where is the skin depth f is the frequency is the average electrical
resistivity and r is the average relative permeability
212 Proximity effect
A changing magnetic field will influence the distribution of an electric current flowing within an electrical conductor by electromagnetic induction When an alternating current flows through an isolated conductor it creates an associated alternating magnetic field around it The alternating magnetic field induces eddy currents in adjacent conductors altering the overall distribution of current flowing through them ndash the distribution of current within the conductor will be constrained to smaller regions Subsequently the resistance is increased in those regions The resulting current crowding is termed the proximity effect Usually the current is concentrated in the areas of the conductor furthest away from nearby conductors carrying current in the same direction [10]
Thus since in our case the inductor is a coil the maximum current density will be at the inner side of the coil [3] So the inner side of the coil will be used to heat the workpiece which will get faster temperature increase and will be more efficient
22 Numerical basis of the induction process
All the physical phenomena encountered in engineering mechanics are modeled by differential equations Usually it is difficult to obtain accurate analytical solution of the differential equation However the numerical solution could be calculated but only when boundary conditions and initial
16
conditions under specific situations were given The following numerical methods are used to model the induction process in LS-DYNA
Finite Element Method
The FEM is today a powerful (often the most powerful) tool for numerical solution of any differential equation whether this arises from structural mechanics fluid mechanics thermodynamics biology ecology or any other field of science [11]
The finite element method is a numerical approach by which general differential equations can be solved in an approximate manner [12] A domain of interest is represented as an assembly of finite elements The FEM is useful for problems with complicated geometries loadings and material properties where analytical solutions cannot be obtained [13]
The main steps in the general FE formulation and solution of a physical problem are [11]
o Establish the strong form of the governing differential equation
o Transform this differential equation into the weak form
o Choose trial functions for the unknown function that is choose element type(s) and mesh the solution domain
o Choose weight functions and establish the system of algebraic equations for each element (element equations)
o Assemble these element systems into the global system of algebraic equations
o Introduce boundary conditions into the global system of algebraic equations
o Solve the system of algebraic equations and present the results or use them for further calculations
Boundary Element Method
The boundary element method (BEM) is a numerical computational method of solving linear partial differential equations which have been formulated as integral equations BEM attempts to use the given boundary conditions to fit only boundary values into the integral equation Once this is done the integral equation can then be used again to calculate numerically solution at any desired point in the interior of the solution domain The boundary
17
element method is often more efficient than other methods including FEM in terms of computational resources for problems where there is a small surfacevolume ratio Conceptually it works by constructing a mesh over the modeled surface However for many problems boundary element methods are significantly less suitable and efficient than volume-discretization methods [14]
In numerical computations of the problem in this thesis with LS-DYNA FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air
221 FEM model for electromagnetic field
In LS-DYNA equation (213) is projected on the 0W forms (0-forms are continuous scalar basis functions that have a well defined gradient the gradient of a 0-form being a 1- form) and equation (214) is projected on
the 1W
forms (1-forms are vector basis functions with continuous tangential components but discontinuous normal components) They have a well defined curl the curl of a 1-form being a 2-form) giving after integrating by part the following weak formulations [15]
00 dW
(216)
dWAndW
dWAdWt
A
11
11
)(
1
(217)
where d an element of volume and the surface of with n
outer normal to
The and A
decompositions on respectfully 0W and 1W
give
0iiw (218)
1iiwaA
(219)
18
When replacing and A
in equation (216) and (217) by (218) and (219) one gets
0)(0 S (220)
SaDaSt
aM
)()
1()( 0111
(221)
where
the stiffness matrix of the 0-forms is given by
dWWjiS ji000 ))((
(222)
the mass matrix of the 1-forms is given by
dWWjiM ji111 ))((
(223)
the stiffness matrix of the 1-forms is given by
dWWjiS ji )()(1
))(1
( 111
(224)
the derivative matrix of the 0-1-forms is given by
dWWjiD ji )())(( 1001
(225)
the outside stiffness matrix is given by
19
dWWnjiS ji11)(
1))(
1(
(226)
where is the magnetic permeability n
is the normal vector is the volume and is the boundary surface of volume
Equation (220) and (221) form the FEM system with and a being the unknowns From this system only the outside stiffness matrix cannot be directly computed The calculation of this matrix will be made possible through the definition of the BEM system [7] The BEM system is used for the air and will not be shown in this report More information about it could be found in [7]
222 FEM model for temperature field
The steady state or transient temperature field on three dimensional geometries can also be solved by LS-DYNA Material properties may be temperature dependent and either isotopic or orthotropic A variety of time and temperature dependent boundary conditions can be specified including temperature flux convection and radiation The implementation of heat conduction into LS-DYNA is based on the work of Shapiro [16]
The differential equations of conduction of heat in a three-dimensional continuum is given by
Qkt
cijij
(227)
where )( txi is temperature )( ix is density )( ixcc is
the specific heat )( iijij xkk is thermal conductivity )( ixQQ is
internal heat generation rate per unit volume
The boundary conditions are
s on 1 (228)
20
ijij nk on 2 (229)
Initial conditions at 0t are given by
)(0 ix at 0tt (230)
where )(txx ii are coordinates as a function of time is prescribed
temperature on 1 and in is normal vector to 2
Equations (227-230) represent the strong form of a boundary value problem to be solved for the temperature field within the solid continuum [16]
The finite element method provides the following equations for the numerical solution of equations (227-230)
nnnnnnn HFHt
C
1 (231)
e
jie
eij
e
dcNNCC (232)
ejiji
T
e
eij
ee
dNNdNKNHH (233)
eigi
e
ei
ee
dNdqNFF (234)
where and are the parameters that are different when using different methods like Crank-Nicolson Galerkin and so on The parameter is taken to be in the interval [01] C H and F are the element stiffness load and boundary matrices respectively N is the element shape functions gq is the heat flow K is the thermal conductivity tensor
21
The boundary conditions for temperature flux convection and radiation are
)(
)(
)(
42
4112 TTF
n
T
TThn
T
qn
Tk
tzyxfT
w
sz
(235)
where T is the temperature k is the thermal conductivity n is the normal direction of the boundary szq
is the heat flux vector h is the convective
heat transfer coefficient wT is the surface temperature of the solid T is
the fluid temperature is the emissivity is the Stefan Boltzmann constant
223 FEM model for mechanical field
The equations that govern analyses of the behavior of a solid continuum are those of momentum conservation ie the equations of motion For an analysis of small deformation of a solid continuum these are (in tensor form) [17]
iijij ub (236)
where ij is the Cauchy stress tensor ib the body force vector per unit
volume the density and iu the displacement vector
To establish a weak form from the strong one we multiply (236) by an arbitrary velocity ie the test function iv and integrate over the region
By introducing two boundary conditions ii uu on u and ijijn on
where 0v on u the above differential equation in the weak form
[17] is given as
22
dvdbvduvdv iiiiiiijji (237)
To perform the FE discretization of the weak form (237) means to divide the continuum volume into sub-elements where the displacement field in every element is approximated by shape functions )(xNI and nodal
displacements )(tuiI that is summation of their products [17]
)()()( xNtutxu IiIi (238)
By approximating the test functions with the same shape functions (Galerkin method) we obtain
0)(
)()(
)(
)(
)(
)(
int)(
int
int
ee
e
e
dNbdNff
NdNMM
x
NBdBff
fuMfv
TTexte
ext
Te
j
IjI
Te
extT
(239)
which must hold for an arbitrary v and which puts the FE equation in order
intffuM ext (240)
For a linear material C the FE equation that emerges is
23
)(
)(e
dCBBKKfKuuM TTeext (241)
224 Numerical procedure
For the induction hardening process three different analyses have been combined in one numerical procedure mechanical thermal-metallurgical and electromagnetic (EM) computations They are solved fully transiently Boundary conditions and material properties beside one unique geometric model were required by each of them
What is necessary to mention is that some characteristics of the material are interdependent The electric conductivity for instance depends on the temperature In addition all thermal properties depend on the temperature [18] The variation of the properties with the temperature makes the system to be non-linear
There is a high coupling grade between thermal and EM equations because the electrical and magnetic properties laws depend on temperature When the initial temperature is known the eddy current value is calculated and then used to compute the heat generated by the Joule effect [5] At each time step the convergence is checked Until a steady state between the heat and the temperature field is reached the temperature value will be recalculated for each magnetic sub-step
EM solver can be coupled with the thermal and mechanical solvers in order to take full advantage of their capabilities [7] Both the thermal and the EM solver run with implicit time integration For mechanical solver there are two time integration methods of explicit and implicit type
Explicit and implicit methods are numerical schemes for obtaining numerical solutions of time-dependent ordinary and partial differential equations as is required in computer simulations of physical processes Explicit methods calculate the state of a system at a later time from the state of the system at the current time while implicit methods find a solution by solving an equation involving both the current state of the system and the later one [19] Here follows the difference between explicit and implicit methods
Implicit method
o More accurate
24
o It has large time step increment
o Convergence of each load step can be controlled to avoid error accumulation
o Iteration may not converge
Explicit method
o Less accurate
o It has small time step
o There is error accumulation and the error is difficult to estimate
o Iteration converges
However the implicit type has been governing the mechanical solver for the induction process in this thesis
Now let us go back to the couplings For the electromagnetic and structure interaction both the mechanical and the EM solver have distinct time steps By linear interpolation the EM fields are evaluated at the mechanical time step The two solvers will interact at each electromagnetic time step The EM solver will communicate the Lorentz force to the mechanical solver [7] resulting in an extra force in the mechanic equation
Lorentzext FfDt
Du (242)
where is total charge density is electrical conductivity extf is the
external force while LorentzF is the Lorentz force In turn the displacements
and deformations of the conductors are returned by the mechanical solver
When it comes to the thermal coupling at each electromagnetic time step the EM solver will communicate the extra Joule heating power term and the thermal solver will communicate the temperature
Figure 22 shows the interactions between the different solvers in LS-DYNA
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
14
where is the electric scalar potential
Equation (210) leaves a mathematical degree of freedom to A
(if A
is
transformed to a given
A then Equation (210) remains valid) Therefore the introduction of a gauge ie a particular choice of the scalar and vector potentials is needed Gauge choosing denotes a mathematical procedure for coping with redundant degrees of freedom in field variables The gauge chosen here is the generalized Coulomb gauge
0 A
(212)
Equations (25) (29) (211) and (212) give
0
(213)
Equations (25) (27) (211) and (210) give
sjAt
A
1
(214)
Equation (213) and Equation (214) are the two equations constituting the system that will be solved where A
and are the two unknowns of the
problem [7]
211 Skin effect and skin depth
Skin effect is the tendency of an alternating electric current (AC) to become distributed within a conductor such that the current density is largest near the surface of the conductor and decreases with greater depths in the conductor [9]
Skin effect is associated with the current flowing mainly at the skin of the conductor at an average depth called the skin depth The skin depth is
15
defined as the depth at which the electromagnetic field in a conducting material has decreased to 037 of its value just outside the material which describes the electric and magnetic fields The formula for the skin depth is given by
ff rr
503
)2(
22
0
(215)
where is the skin depth f is the frequency is the average electrical
resistivity and r is the average relative permeability
212 Proximity effect
A changing magnetic field will influence the distribution of an electric current flowing within an electrical conductor by electromagnetic induction When an alternating current flows through an isolated conductor it creates an associated alternating magnetic field around it The alternating magnetic field induces eddy currents in adjacent conductors altering the overall distribution of current flowing through them ndash the distribution of current within the conductor will be constrained to smaller regions Subsequently the resistance is increased in those regions The resulting current crowding is termed the proximity effect Usually the current is concentrated in the areas of the conductor furthest away from nearby conductors carrying current in the same direction [10]
Thus since in our case the inductor is a coil the maximum current density will be at the inner side of the coil [3] So the inner side of the coil will be used to heat the workpiece which will get faster temperature increase and will be more efficient
22 Numerical basis of the induction process
All the physical phenomena encountered in engineering mechanics are modeled by differential equations Usually it is difficult to obtain accurate analytical solution of the differential equation However the numerical solution could be calculated but only when boundary conditions and initial
16
conditions under specific situations were given The following numerical methods are used to model the induction process in LS-DYNA
Finite Element Method
The FEM is today a powerful (often the most powerful) tool for numerical solution of any differential equation whether this arises from structural mechanics fluid mechanics thermodynamics biology ecology or any other field of science [11]
The finite element method is a numerical approach by which general differential equations can be solved in an approximate manner [12] A domain of interest is represented as an assembly of finite elements The FEM is useful for problems with complicated geometries loadings and material properties where analytical solutions cannot be obtained [13]
The main steps in the general FE formulation and solution of a physical problem are [11]
o Establish the strong form of the governing differential equation
o Transform this differential equation into the weak form
o Choose trial functions for the unknown function that is choose element type(s) and mesh the solution domain
o Choose weight functions and establish the system of algebraic equations for each element (element equations)
o Assemble these element systems into the global system of algebraic equations
o Introduce boundary conditions into the global system of algebraic equations
o Solve the system of algebraic equations and present the results or use them for further calculations
Boundary Element Method
The boundary element method (BEM) is a numerical computational method of solving linear partial differential equations which have been formulated as integral equations BEM attempts to use the given boundary conditions to fit only boundary values into the integral equation Once this is done the integral equation can then be used again to calculate numerically solution at any desired point in the interior of the solution domain The boundary
17
element method is often more efficient than other methods including FEM in terms of computational resources for problems where there is a small surfacevolume ratio Conceptually it works by constructing a mesh over the modeled surface However for many problems boundary element methods are significantly less suitable and efficient than volume-discretization methods [14]
In numerical computations of the problem in this thesis with LS-DYNA FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air
221 FEM model for electromagnetic field
In LS-DYNA equation (213) is projected on the 0W forms (0-forms are continuous scalar basis functions that have a well defined gradient the gradient of a 0-form being a 1- form) and equation (214) is projected on
the 1W
forms (1-forms are vector basis functions with continuous tangential components but discontinuous normal components) They have a well defined curl the curl of a 1-form being a 2-form) giving after integrating by part the following weak formulations [15]
00 dW
(216)
dWAndW
dWAdWt
A
11
11
)(
1
(217)
where d an element of volume and the surface of with n
outer normal to
The and A
decompositions on respectfully 0W and 1W
give
0iiw (218)
1iiwaA
(219)
18
When replacing and A
in equation (216) and (217) by (218) and (219) one gets
0)(0 S (220)
SaDaSt
aM
)()
1()( 0111
(221)
where
the stiffness matrix of the 0-forms is given by
dWWjiS ji000 ))((
(222)
the mass matrix of the 1-forms is given by
dWWjiM ji111 ))((
(223)
the stiffness matrix of the 1-forms is given by
dWWjiS ji )()(1
))(1
( 111
(224)
the derivative matrix of the 0-1-forms is given by
dWWjiD ji )())(( 1001
(225)
the outside stiffness matrix is given by
19
dWWnjiS ji11)(
1))(
1(
(226)
where is the magnetic permeability n
is the normal vector is the volume and is the boundary surface of volume
Equation (220) and (221) form the FEM system with and a being the unknowns From this system only the outside stiffness matrix cannot be directly computed The calculation of this matrix will be made possible through the definition of the BEM system [7] The BEM system is used for the air and will not be shown in this report More information about it could be found in [7]
222 FEM model for temperature field
The steady state or transient temperature field on three dimensional geometries can also be solved by LS-DYNA Material properties may be temperature dependent and either isotopic or orthotropic A variety of time and temperature dependent boundary conditions can be specified including temperature flux convection and radiation The implementation of heat conduction into LS-DYNA is based on the work of Shapiro [16]
The differential equations of conduction of heat in a three-dimensional continuum is given by
Qkt
cijij
(227)
where )( txi is temperature )( ix is density )( ixcc is
the specific heat )( iijij xkk is thermal conductivity )( ixQQ is
internal heat generation rate per unit volume
The boundary conditions are
s on 1 (228)
20
ijij nk on 2 (229)
Initial conditions at 0t are given by
)(0 ix at 0tt (230)
where )(txx ii are coordinates as a function of time is prescribed
temperature on 1 and in is normal vector to 2
Equations (227-230) represent the strong form of a boundary value problem to be solved for the temperature field within the solid continuum [16]
The finite element method provides the following equations for the numerical solution of equations (227-230)
nnnnnnn HFHt
C
1 (231)
e
jie
eij
e
dcNNCC (232)
ejiji
T
e
eij
ee
dNNdNKNHH (233)
eigi
e
ei
ee
dNdqNFF (234)
where and are the parameters that are different when using different methods like Crank-Nicolson Galerkin and so on The parameter is taken to be in the interval [01] C H and F are the element stiffness load and boundary matrices respectively N is the element shape functions gq is the heat flow K is the thermal conductivity tensor
21
The boundary conditions for temperature flux convection and radiation are
)(
)(
)(
42
4112 TTF
n
T
TThn
T
qn
Tk
tzyxfT
w
sz
(235)
where T is the temperature k is the thermal conductivity n is the normal direction of the boundary szq
is the heat flux vector h is the convective
heat transfer coefficient wT is the surface temperature of the solid T is
the fluid temperature is the emissivity is the Stefan Boltzmann constant
223 FEM model for mechanical field
The equations that govern analyses of the behavior of a solid continuum are those of momentum conservation ie the equations of motion For an analysis of small deformation of a solid continuum these are (in tensor form) [17]
iijij ub (236)
where ij is the Cauchy stress tensor ib the body force vector per unit
volume the density and iu the displacement vector
To establish a weak form from the strong one we multiply (236) by an arbitrary velocity ie the test function iv and integrate over the region
By introducing two boundary conditions ii uu on u and ijijn on
where 0v on u the above differential equation in the weak form
[17] is given as
22
dvdbvduvdv iiiiiiijji (237)
To perform the FE discretization of the weak form (237) means to divide the continuum volume into sub-elements where the displacement field in every element is approximated by shape functions )(xNI and nodal
displacements )(tuiI that is summation of their products [17]
)()()( xNtutxu IiIi (238)
By approximating the test functions with the same shape functions (Galerkin method) we obtain
0)(
)()(
)(
)(
)(
)(
int)(
int
int
ee
e
e
dNbdNff
NdNMM
x
NBdBff
fuMfv
TTexte
ext
Te
j
IjI
Te
extT
(239)
which must hold for an arbitrary v and which puts the FE equation in order
intffuM ext (240)
For a linear material C the FE equation that emerges is
23
)(
)(e
dCBBKKfKuuM TTeext (241)
224 Numerical procedure
For the induction hardening process three different analyses have been combined in one numerical procedure mechanical thermal-metallurgical and electromagnetic (EM) computations They are solved fully transiently Boundary conditions and material properties beside one unique geometric model were required by each of them
What is necessary to mention is that some characteristics of the material are interdependent The electric conductivity for instance depends on the temperature In addition all thermal properties depend on the temperature [18] The variation of the properties with the temperature makes the system to be non-linear
There is a high coupling grade between thermal and EM equations because the electrical and magnetic properties laws depend on temperature When the initial temperature is known the eddy current value is calculated and then used to compute the heat generated by the Joule effect [5] At each time step the convergence is checked Until a steady state between the heat and the temperature field is reached the temperature value will be recalculated for each magnetic sub-step
EM solver can be coupled with the thermal and mechanical solvers in order to take full advantage of their capabilities [7] Both the thermal and the EM solver run with implicit time integration For mechanical solver there are two time integration methods of explicit and implicit type
Explicit and implicit methods are numerical schemes for obtaining numerical solutions of time-dependent ordinary and partial differential equations as is required in computer simulations of physical processes Explicit methods calculate the state of a system at a later time from the state of the system at the current time while implicit methods find a solution by solving an equation involving both the current state of the system and the later one [19] Here follows the difference between explicit and implicit methods
Implicit method
o More accurate
24
o It has large time step increment
o Convergence of each load step can be controlled to avoid error accumulation
o Iteration may not converge
Explicit method
o Less accurate
o It has small time step
o There is error accumulation and the error is difficult to estimate
o Iteration converges
However the implicit type has been governing the mechanical solver for the induction process in this thesis
Now let us go back to the couplings For the electromagnetic and structure interaction both the mechanical and the EM solver have distinct time steps By linear interpolation the EM fields are evaluated at the mechanical time step The two solvers will interact at each electromagnetic time step The EM solver will communicate the Lorentz force to the mechanical solver [7] resulting in an extra force in the mechanic equation
Lorentzext FfDt
Du (242)
where is total charge density is electrical conductivity extf is the
external force while LorentzF is the Lorentz force In turn the displacements
and deformations of the conductors are returned by the mechanical solver
When it comes to the thermal coupling at each electromagnetic time step the EM solver will communicate the extra Joule heating power term and the thermal solver will communicate the temperature
Figure 22 shows the interactions between the different solvers in LS-DYNA
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
15
defined as the depth at which the electromagnetic field in a conducting material has decreased to 037 of its value just outside the material which describes the electric and magnetic fields The formula for the skin depth is given by
ff rr
503
)2(
22
0
(215)
where is the skin depth f is the frequency is the average electrical
resistivity and r is the average relative permeability
212 Proximity effect
A changing magnetic field will influence the distribution of an electric current flowing within an electrical conductor by electromagnetic induction When an alternating current flows through an isolated conductor it creates an associated alternating magnetic field around it The alternating magnetic field induces eddy currents in adjacent conductors altering the overall distribution of current flowing through them ndash the distribution of current within the conductor will be constrained to smaller regions Subsequently the resistance is increased in those regions The resulting current crowding is termed the proximity effect Usually the current is concentrated in the areas of the conductor furthest away from nearby conductors carrying current in the same direction [10]
Thus since in our case the inductor is a coil the maximum current density will be at the inner side of the coil [3] So the inner side of the coil will be used to heat the workpiece which will get faster temperature increase and will be more efficient
22 Numerical basis of the induction process
All the physical phenomena encountered in engineering mechanics are modeled by differential equations Usually it is difficult to obtain accurate analytical solution of the differential equation However the numerical solution could be calculated but only when boundary conditions and initial
16
conditions under specific situations were given The following numerical methods are used to model the induction process in LS-DYNA
Finite Element Method
The FEM is today a powerful (often the most powerful) tool for numerical solution of any differential equation whether this arises from structural mechanics fluid mechanics thermodynamics biology ecology or any other field of science [11]
The finite element method is a numerical approach by which general differential equations can be solved in an approximate manner [12] A domain of interest is represented as an assembly of finite elements The FEM is useful for problems with complicated geometries loadings and material properties where analytical solutions cannot be obtained [13]
The main steps in the general FE formulation and solution of a physical problem are [11]
o Establish the strong form of the governing differential equation
o Transform this differential equation into the weak form
o Choose trial functions for the unknown function that is choose element type(s) and mesh the solution domain
o Choose weight functions and establish the system of algebraic equations for each element (element equations)
o Assemble these element systems into the global system of algebraic equations
o Introduce boundary conditions into the global system of algebraic equations
o Solve the system of algebraic equations and present the results or use them for further calculations
Boundary Element Method
The boundary element method (BEM) is a numerical computational method of solving linear partial differential equations which have been formulated as integral equations BEM attempts to use the given boundary conditions to fit only boundary values into the integral equation Once this is done the integral equation can then be used again to calculate numerically solution at any desired point in the interior of the solution domain The boundary
17
element method is often more efficient than other methods including FEM in terms of computational resources for problems where there is a small surfacevolume ratio Conceptually it works by constructing a mesh over the modeled surface However for many problems boundary element methods are significantly less suitable and efficient than volume-discretization methods [14]
In numerical computations of the problem in this thesis with LS-DYNA FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air
221 FEM model for electromagnetic field
In LS-DYNA equation (213) is projected on the 0W forms (0-forms are continuous scalar basis functions that have a well defined gradient the gradient of a 0-form being a 1- form) and equation (214) is projected on
the 1W
forms (1-forms are vector basis functions with continuous tangential components but discontinuous normal components) They have a well defined curl the curl of a 1-form being a 2-form) giving after integrating by part the following weak formulations [15]
00 dW
(216)
dWAndW
dWAdWt
A
11
11
)(
1
(217)
where d an element of volume and the surface of with n
outer normal to
The and A
decompositions on respectfully 0W and 1W
give
0iiw (218)
1iiwaA
(219)
18
When replacing and A
in equation (216) and (217) by (218) and (219) one gets
0)(0 S (220)
SaDaSt
aM
)()
1()( 0111
(221)
where
the stiffness matrix of the 0-forms is given by
dWWjiS ji000 ))((
(222)
the mass matrix of the 1-forms is given by
dWWjiM ji111 ))((
(223)
the stiffness matrix of the 1-forms is given by
dWWjiS ji )()(1
))(1
( 111
(224)
the derivative matrix of the 0-1-forms is given by
dWWjiD ji )())(( 1001
(225)
the outside stiffness matrix is given by
19
dWWnjiS ji11)(
1))(
1(
(226)
where is the magnetic permeability n
is the normal vector is the volume and is the boundary surface of volume
Equation (220) and (221) form the FEM system with and a being the unknowns From this system only the outside stiffness matrix cannot be directly computed The calculation of this matrix will be made possible through the definition of the BEM system [7] The BEM system is used for the air and will not be shown in this report More information about it could be found in [7]
222 FEM model for temperature field
The steady state or transient temperature field on three dimensional geometries can also be solved by LS-DYNA Material properties may be temperature dependent and either isotopic or orthotropic A variety of time and temperature dependent boundary conditions can be specified including temperature flux convection and radiation The implementation of heat conduction into LS-DYNA is based on the work of Shapiro [16]
The differential equations of conduction of heat in a three-dimensional continuum is given by
Qkt
cijij
(227)
where )( txi is temperature )( ix is density )( ixcc is
the specific heat )( iijij xkk is thermal conductivity )( ixQQ is
internal heat generation rate per unit volume
The boundary conditions are
s on 1 (228)
20
ijij nk on 2 (229)
Initial conditions at 0t are given by
)(0 ix at 0tt (230)
where )(txx ii are coordinates as a function of time is prescribed
temperature on 1 and in is normal vector to 2
Equations (227-230) represent the strong form of a boundary value problem to be solved for the temperature field within the solid continuum [16]
The finite element method provides the following equations for the numerical solution of equations (227-230)
nnnnnnn HFHt
C
1 (231)
e
jie
eij
e
dcNNCC (232)
ejiji
T
e
eij
ee
dNNdNKNHH (233)
eigi
e
ei
ee
dNdqNFF (234)
where and are the parameters that are different when using different methods like Crank-Nicolson Galerkin and so on The parameter is taken to be in the interval [01] C H and F are the element stiffness load and boundary matrices respectively N is the element shape functions gq is the heat flow K is the thermal conductivity tensor
21
The boundary conditions for temperature flux convection and radiation are
)(
)(
)(
42
4112 TTF
n
T
TThn
T
qn
Tk
tzyxfT
w
sz
(235)
where T is the temperature k is the thermal conductivity n is the normal direction of the boundary szq
is the heat flux vector h is the convective
heat transfer coefficient wT is the surface temperature of the solid T is
the fluid temperature is the emissivity is the Stefan Boltzmann constant
223 FEM model for mechanical field
The equations that govern analyses of the behavior of a solid continuum are those of momentum conservation ie the equations of motion For an analysis of small deformation of a solid continuum these are (in tensor form) [17]
iijij ub (236)
where ij is the Cauchy stress tensor ib the body force vector per unit
volume the density and iu the displacement vector
To establish a weak form from the strong one we multiply (236) by an arbitrary velocity ie the test function iv and integrate over the region
By introducing two boundary conditions ii uu on u and ijijn on
where 0v on u the above differential equation in the weak form
[17] is given as
22
dvdbvduvdv iiiiiiijji (237)
To perform the FE discretization of the weak form (237) means to divide the continuum volume into sub-elements where the displacement field in every element is approximated by shape functions )(xNI and nodal
displacements )(tuiI that is summation of their products [17]
)()()( xNtutxu IiIi (238)
By approximating the test functions with the same shape functions (Galerkin method) we obtain
0)(
)()(
)(
)(
)(
)(
int)(
int
int
ee
e
e
dNbdNff
NdNMM
x
NBdBff
fuMfv
TTexte
ext
Te
j
IjI
Te
extT
(239)
which must hold for an arbitrary v and which puts the FE equation in order
intffuM ext (240)
For a linear material C the FE equation that emerges is
23
)(
)(e
dCBBKKfKuuM TTeext (241)
224 Numerical procedure
For the induction hardening process three different analyses have been combined in one numerical procedure mechanical thermal-metallurgical and electromagnetic (EM) computations They are solved fully transiently Boundary conditions and material properties beside one unique geometric model were required by each of them
What is necessary to mention is that some characteristics of the material are interdependent The electric conductivity for instance depends on the temperature In addition all thermal properties depend on the temperature [18] The variation of the properties with the temperature makes the system to be non-linear
There is a high coupling grade between thermal and EM equations because the electrical and magnetic properties laws depend on temperature When the initial temperature is known the eddy current value is calculated and then used to compute the heat generated by the Joule effect [5] At each time step the convergence is checked Until a steady state between the heat and the temperature field is reached the temperature value will be recalculated for each magnetic sub-step
EM solver can be coupled with the thermal and mechanical solvers in order to take full advantage of their capabilities [7] Both the thermal and the EM solver run with implicit time integration For mechanical solver there are two time integration methods of explicit and implicit type
Explicit and implicit methods are numerical schemes for obtaining numerical solutions of time-dependent ordinary and partial differential equations as is required in computer simulations of physical processes Explicit methods calculate the state of a system at a later time from the state of the system at the current time while implicit methods find a solution by solving an equation involving both the current state of the system and the later one [19] Here follows the difference between explicit and implicit methods
Implicit method
o More accurate
24
o It has large time step increment
o Convergence of each load step can be controlled to avoid error accumulation
o Iteration may not converge
Explicit method
o Less accurate
o It has small time step
o There is error accumulation and the error is difficult to estimate
o Iteration converges
However the implicit type has been governing the mechanical solver for the induction process in this thesis
Now let us go back to the couplings For the electromagnetic and structure interaction both the mechanical and the EM solver have distinct time steps By linear interpolation the EM fields are evaluated at the mechanical time step The two solvers will interact at each electromagnetic time step The EM solver will communicate the Lorentz force to the mechanical solver [7] resulting in an extra force in the mechanic equation
Lorentzext FfDt
Du (242)
where is total charge density is electrical conductivity extf is the
external force while LorentzF is the Lorentz force In turn the displacements
and deformations of the conductors are returned by the mechanical solver
When it comes to the thermal coupling at each electromagnetic time step the EM solver will communicate the extra Joule heating power term and the thermal solver will communicate the temperature
Figure 22 shows the interactions between the different solvers in LS-DYNA
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
16
conditions under specific situations were given The following numerical methods are used to model the induction process in LS-DYNA
Finite Element Method
The FEM is today a powerful (often the most powerful) tool for numerical solution of any differential equation whether this arises from structural mechanics fluid mechanics thermodynamics biology ecology or any other field of science [11]
The finite element method is a numerical approach by which general differential equations can be solved in an approximate manner [12] A domain of interest is represented as an assembly of finite elements The FEM is useful for problems with complicated geometries loadings and material properties where analytical solutions cannot be obtained [13]
The main steps in the general FE formulation and solution of a physical problem are [11]
o Establish the strong form of the governing differential equation
o Transform this differential equation into the weak form
o Choose trial functions for the unknown function that is choose element type(s) and mesh the solution domain
o Choose weight functions and establish the system of algebraic equations for each element (element equations)
o Assemble these element systems into the global system of algebraic equations
o Introduce boundary conditions into the global system of algebraic equations
o Solve the system of algebraic equations and present the results or use them for further calculations
Boundary Element Method
The boundary element method (BEM) is a numerical computational method of solving linear partial differential equations which have been formulated as integral equations BEM attempts to use the given boundary conditions to fit only boundary values into the integral equation Once this is done the integral equation can then be used again to calculate numerically solution at any desired point in the interior of the solution domain The boundary
17
element method is often more efficient than other methods including FEM in terms of computational resources for problems where there is a small surfacevolume ratio Conceptually it works by constructing a mesh over the modeled surface However for many problems boundary element methods are significantly less suitable and efficient than volume-discretization methods [14]
In numerical computations of the problem in this thesis with LS-DYNA FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air
221 FEM model for electromagnetic field
In LS-DYNA equation (213) is projected on the 0W forms (0-forms are continuous scalar basis functions that have a well defined gradient the gradient of a 0-form being a 1- form) and equation (214) is projected on
the 1W
forms (1-forms are vector basis functions with continuous tangential components but discontinuous normal components) They have a well defined curl the curl of a 1-form being a 2-form) giving after integrating by part the following weak formulations [15]
00 dW
(216)
dWAndW
dWAdWt
A
11
11
)(
1
(217)
where d an element of volume and the surface of with n
outer normal to
The and A
decompositions on respectfully 0W and 1W
give
0iiw (218)
1iiwaA
(219)
18
When replacing and A
in equation (216) and (217) by (218) and (219) one gets
0)(0 S (220)
SaDaSt
aM
)()
1()( 0111
(221)
where
the stiffness matrix of the 0-forms is given by
dWWjiS ji000 ))((
(222)
the mass matrix of the 1-forms is given by
dWWjiM ji111 ))((
(223)
the stiffness matrix of the 1-forms is given by
dWWjiS ji )()(1
))(1
( 111
(224)
the derivative matrix of the 0-1-forms is given by
dWWjiD ji )())(( 1001
(225)
the outside stiffness matrix is given by
19
dWWnjiS ji11)(
1))(
1(
(226)
where is the magnetic permeability n
is the normal vector is the volume and is the boundary surface of volume
Equation (220) and (221) form the FEM system with and a being the unknowns From this system only the outside stiffness matrix cannot be directly computed The calculation of this matrix will be made possible through the definition of the BEM system [7] The BEM system is used for the air and will not be shown in this report More information about it could be found in [7]
222 FEM model for temperature field
The steady state or transient temperature field on three dimensional geometries can also be solved by LS-DYNA Material properties may be temperature dependent and either isotopic or orthotropic A variety of time and temperature dependent boundary conditions can be specified including temperature flux convection and radiation The implementation of heat conduction into LS-DYNA is based on the work of Shapiro [16]
The differential equations of conduction of heat in a three-dimensional continuum is given by
Qkt
cijij
(227)
where )( txi is temperature )( ix is density )( ixcc is
the specific heat )( iijij xkk is thermal conductivity )( ixQQ is
internal heat generation rate per unit volume
The boundary conditions are
s on 1 (228)
20
ijij nk on 2 (229)
Initial conditions at 0t are given by
)(0 ix at 0tt (230)
where )(txx ii are coordinates as a function of time is prescribed
temperature on 1 and in is normal vector to 2
Equations (227-230) represent the strong form of a boundary value problem to be solved for the temperature field within the solid continuum [16]
The finite element method provides the following equations for the numerical solution of equations (227-230)
nnnnnnn HFHt
C
1 (231)
e
jie
eij
e
dcNNCC (232)
ejiji
T
e
eij
ee
dNNdNKNHH (233)
eigi
e
ei
ee
dNdqNFF (234)
where and are the parameters that are different when using different methods like Crank-Nicolson Galerkin and so on The parameter is taken to be in the interval [01] C H and F are the element stiffness load and boundary matrices respectively N is the element shape functions gq is the heat flow K is the thermal conductivity tensor
21
The boundary conditions for temperature flux convection and radiation are
)(
)(
)(
42
4112 TTF
n
T
TThn
T
qn
Tk
tzyxfT
w
sz
(235)
where T is the temperature k is the thermal conductivity n is the normal direction of the boundary szq
is the heat flux vector h is the convective
heat transfer coefficient wT is the surface temperature of the solid T is
the fluid temperature is the emissivity is the Stefan Boltzmann constant
223 FEM model for mechanical field
The equations that govern analyses of the behavior of a solid continuum are those of momentum conservation ie the equations of motion For an analysis of small deformation of a solid continuum these are (in tensor form) [17]
iijij ub (236)
where ij is the Cauchy stress tensor ib the body force vector per unit
volume the density and iu the displacement vector
To establish a weak form from the strong one we multiply (236) by an arbitrary velocity ie the test function iv and integrate over the region
By introducing two boundary conditions ii uu on u and ijijn on
where 0v on u the above differential equation in the weak form
[17] is given as
22
dvdbvduvdv iiiiiiijji (237)
To perform the FE discretization of the weak form (237) means to divide the continuum volume into sub-elements where the displacement field in every element is approximated by shape functions )(xNI and nodal
displacements )(tuiI that is summation of their products [17]
)()()( xNtutxu IiIi (238)
By approximating the test functions with the same shape functions (Galerkin method) we obtain
0)(
)()(
)(
)(
)(
)(
int)(
int
int
ee
e
e
dNbdNff
NdNMM
x
NBdBff
fuMfv
TTexte
ext
Te
j
IjI
Te
extT
(239)
which must hold for an arbitrary v and which puts the FE equation in order
intffuM ext (240)
For a linear material C the FE equation that emerges is
23
)(
)(e
dCBBKKfKuuM TTeext (241)
224 Numerical procedure
For the induction hardening process three different analyses have been combined in one numerical procedure mechanical thermal-metallurgical and electromagnetic (EM) computations They are solved fully transiently Boundary conditions and material properties beside one unique geometric model were required by each of them
What is necessary to mention is that some characteristics of the material are interdependent The electric conductivity for instance depends on the temperature In addition all thermal properties depend on the temperature [18] The variation of the properties with the temperature makes the system to be non-linear
There is a high coupling grade between thermal and EM equations because the electrical and magnetic properties laws depend on temperature When the initial temperature is known the eddy current value is calculated and then used to compute the heat generated by the Joule effect [5] At each time step the convergence is checked Until a steady state between the heat and the temperature field is reached the temperature value will be recalculated for each magnetic sub-step
EM solver can be coupled with the thermal and mechanical solvers in order to take full advantage of their capabilities [7] Both the thermal and the EM solver run with implicit time integration For mechanical solver there are two time integration methods of explicit and implicit type
Explicit and implicit methods are numerical schemes for obtaining numerical solutions of time-dependent ordinary and partial differential equations as is required in computer simulations of physical processes Explicit methods calculate the state of a system at a later time from the state of the system at the current time while implicit methods find a solution by solving an equation involving both the current state of the system and the later one [19] Here follows the difference between explicit and implicit methods
Implicit method
o More accurate
24
o It has large time step increment
o Convergence of each load step can be controlled to avoid error accumulation
o Iteration may not converge
Explicit method
o Less accurate
o It has small time step
o There is error accumulation and the error is difficult to estimate
o Iteration converges
However the implicit type has been governing the mechanical solver for the induction process in this thesis
Now let us go back to the couplings For the electromagnetic and structure interaction both the mechanical and the EM solver have distinct time steps By linear interpolation the EM fields are evaluated at the mechanical time step The two solvers will interact at each electromagnetic time step The EM solver will communicate the Lorentz force to the mechanical solver [7] resulting in an extra force in the mechanic equation
Lorentzext FfDt
Du (242)
where is total charge density is electrical conductivity extf is the
external force while LorentzF is the Lorentz force In turn the displacements
and deformations of the conductors are returned by the mechanical solver
When it comes to the thermal coupling at each electromagnetic time step the EM solver will communicate the extra Joule heating power term and the thermal solver will communicate the temperature
Figure 22 shows the interactions between the different solvers in LS-DYNA
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
17
element method is often more efficient than other methods including FEM in terms of computational resources for problems where there is a small surfacevolume ratio Conceptually it works by constructing a mesh over the modeled surface However for many problems boundary element methods are significantly less suitable and efficient than volume-discretization methods [14]
In numerical computations of the problem in this thesis with LS-DYNA FEM is used for conducting pieces only while the FEM-BEM coupling handles heatelectromagnetic propagation through air
221 FEM model for electromagnetic field
In LS-DYNA equation (213) is projected on the 0W forms (0-forms are continuous scalar basis functions that have a well defined gradient the gradient of a 0-form being a 1- form) and equation (214) is projected on
the 1W
forms (1-forms are vector basis functions with continuous tangential components but discontinuous normal components) They have a well defined curl the curl of a 1-form being a 2-form) giving after integrating by part the following weak formulations [15]
00 dW
(216)
dWAndW
dWAdWt
A
11
11
)(
1
(217)
where d an element of volume and the surface of with n
outer normal to
The and A
decompositions on respectfully 0W and 1W
give
0iiw (218)
1iiwaA
(219)
18
When replacing and A
in equation (216) and (217) by (218) and (219) one gets
0)(0 S (220)
SaDaSt
aM
)()
1()( 0111
(221)
where
the stiffness matrix of the 0-forms is given by
dWWjiS ji000 ))((
(222)
the mass matrix of the 1-forms is given by
dWWjiM ji111 ))((
(223)
the stiffness matrix of the 1-forms is given by
dWWjiS ji )()(1
))(1
( 111
(224)
the derivative matrix of the 0-1-forms is given by
dWWjiD ji )())(( 1001
(225)
the outside stiffness matrix is given by
19
dWWnjiS ji11)(
1))(
1(
(226)
where is the magnetic permeability n
is the normal vector is the volume and is the boundary surface of volume
Equation (220) and (221) form the FEM system with and a being the unknowns From this system only the outside stiffness matrix cannot be directly computed The calculation of this matrix will be made possible through the definition of the BEM system [7] The BEM system is used for the air and will not be shown in this report More information about it could be found in [7]
222 FEM model for temperature field
The steady state or transient temperature field on three dimensional geometries can also be solved by LS-DYNA Material properties may be temperature dependent and either isotopic or orthotropic A variety of time and temperature dependent boundary conditions can be specified including temperature flux convection and radiation The implementation of heat conduction into LS-DYNA is based on the work of Shapiro [16]
The differential equations of conduction of heat in a three-dimensional continuum is given by
Qkt
cijij
(227)
where )( txi is temperature )( ix is density )( ixcc is
the specific heat )( iijij xkk is thermal conductivity )( ixQQ is
internal heat generation rate per unit volume
The boundary conditions are
s on 1 (228)
20
ijij nk on 2 (229)
Initial conditions at 0t are given by
)(0 ix at 0tt (230)
where )(txx ii are coordinates as a function of time is prescribed
temperature on 1 and in is normal vector to 2
Equations (227-230) represent the strong form of a boundary value problem to be solved for the temperature field within the solid continuum [16]
The finite element method provides the following equations for the numerical solution of equations (227-230)
nnnnnnn HFHt
C
1 (231)
e
jie
eij
e
dcNNCC (232)
ejiji
T
e
eij
ee
dNNdNKNHH (233)
eigi
e
ei
ee
dNdqNFF (234)
where and are the parameters that are different when using different methods like Crank-Nicolson Galerkin and so on The parameter is taken to be in the interval [01] C H and F are the element stiffness load and boundary matrices respectively N is the element shape functions gq is the heat flow K is the thermal conductivity tensor
21
The boundary conditions for temperature flux convection and radiation are
)(
)(
)(
42
4112 TTF
n
T
TThn
T
qn
Tk
tzyxfT
w
sz
(235)
where T is the temperature k is the thermal conductivity n is the normal direction of the boundary szq
is the heat flux vector h is the convective
heat transfer coefficient wT is the surface temperature of the solid T is
the fluid temperature is the emissivity is the Stefan Boltzmann constant
223 FEM model for mechanical field
The equations that govern analyses of the behavior of a solid continuum are those of momentum conservation ie the equations of motion For an analysis of small deformation of a solid continuum these are (in tensor form) [17]
iijij ub (236)
where ij is the Cauchy stress tensor ib the body force vector per unit
volume the density and iu the displacement vector
To establish a weak form from the strong one we multiply (236) by an arbitrary velocity ie the test function iv and integrate over the region
By introducing two boundary conditions ii uu on u and ijijn on
where 0v on u the above differential equation in the weak form
[17] is given as
22
dvdbvduvdv iiiiiiijji (237)
To perform the FE discretization of the weak form (237) means to divide the continuum volume into sub-elements where the displacement field in every element is approximated by shape functions )(xNI and nodal
displacements )(tuiI that is summation of their products [17]
)()()( xNtutxu IiIi (238)
By approximating the test functions with the same shape functions (Galerkin method) we obtain
0)(
)()(
)(
)(
)(
)(
int)(
int
int
ee
e
e
dNbdNff
NdNMM
x
NBdBff
fuMfv
TTexte
ext
Te
j
IjI
Te
extT
(239)
which must hold for an arbitrary v and which puts the FE equation in order
intffuM ext (240)
For a linear material C the FE equation that emerges is
23
)(
)(e
dCBBKKfKuuM TTeext (241)
224 Numerical procedure
For the induction hardening process three different analyses have been combined in one numerical procedure mechanical thermal-metallurgical and electromagnetic (EM) computations They are solved fully transiently Boundary conditions and material properties beside one unique geometric model were required by each of them
What is necessary to mention is that some characteristics of the material are interdependent The electric conductivity for instance depends on the temperature In addition all thermal properties depend on the temperature [18] The variation of the properties with the temperature makes the system to be non-linear
There is a high coupling grade between thermal and EM equations because the electrical and magnetic properties laws depend on temperature When the initial temperature is known the eddy current value is calculated and then used to compute the heat generated by the Joule effect [5] At each time step the convergence is checked Until a steady state between the heat and the temperature field is reached the temperature value will be recalculated for each magnetic sub-step
EM solver can be coupled with the thermal and mechanical solvers in order to take full advantage of their capabilities [7] Both the thermal and the EM solver run with implicit time integration For mechanical solver there are two time integration methods of explicit and implicit type
Explicit and implicit methods are numerical schemes for obtaining numerical solutions of time-dependent ordinary and partial differential equations as is required in computer simulations of physical processes Explicit methods calculate the state of a system at a later time from the state of the system at the current time while implicit methods find a solution by solving an equation involving both the current state of the system and the later one [19] Here follows the difference between explicit and implicit methods
Implicit method
o More accurate
24
o It has large time step increment
o Convergence of each load step can be controlled to avoid error accumulation
o Iteration may not converge
Explicit method
o Less accurate
o It has small time step
o There is error accumulation and the error is difficult to estimate
o Iteration converges
However the implicit type has been governing the mechanical solver for the induction process in this thesis
Now let us go back to the couplings For the electromagnetic and structure interaction both the mechanical and the EM solver have distinct time steps By linear interpolation the EM fields are evaluated at the mechanical time step The two solvers will interact at each electromagnetic time step The EM solver will communicate the Lorentz force to the mechanical solver [7] resulting in an extra force in the mechanic equation
Lorentzext FfDt
Du (242)
where is total charge density is electrical conductivity extf is the
external force while LorentzF is the Lorentz force In turn the displacements
and deformations of the conductors are returned by the mechanical solver
When it comes to the thermal coupling at each electromagnetic time step the EM solver will communicate the extra Joule heating power term and the thermal solver will communicate the temperature
Figure 22 shows the interactions between the different solvers in LS-DYNA
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
18
When replacing and A
in equation (216) and (217) by (218) and (219) one gets
0)(0 S (220)
SaDaSt
aM
)()
1()( 0111
(221)
where
the stiffness matrix of the 0-forms is given by
dWWjiS ji000 ))((
(222)
the mass matrix of the 1-forms is given by
dWWjiM ji111 ))((
(223)
the stiffness matrix of the 1-forms is given by
dWWjiS ji )()(1
))(1
( 111
(224)
the derivative matrix of the 0-1-forms is given by
dWWjiD ji )())(( 1001
(225)
the outside stiffness matrix is given by
19
dWWnjiS ji11)(
1))(
1(
(226)
where is the magnetic permeability n
is the normal vector is the volume and is the boundary surface of volume
Equation (220) and (221) form the FEM system with and a being the unknowns From this system only the outside stiffness matrix cannot be directly computed The calculation of this matrix will be made possible through the definition of the BEM system [7] The BEM system is used for the air and will not be shown in this report More information about it could be found in [7]
222 FEM model for temperature field
The steady state or transient temperature field on three dimensional geometries can also be solved by LS-DYNA Material properties may be temperature dependent and either isotopic or orthotropic A variety of time and temperature dependent boundary conditions can be specified including temperature flux convection and radiation The implementation of heat conduction into LS-DYNA is based on the work of Shapiro [16]
The differential equations of conduction of heat in a three-dimensional continuum is given by
Qkt
cijij
(227)
where )( txi is temperature )( ix is density )( ixcc is
the specific heat )( iijij xkk is thermal conductivity )( ixQQ is
internal heat generation rate per unit volume
The boundary conditions are
s on 1 (228)
20
ijij nk on 2 (229)
Initial conditions at 0t are given by
)(0 ix at 0tt (230)
where )(txx ii are coordinates as a function of time is prescribed
temperature on 1 and in is normal vector to 2
Equations (227-230) represent the strong form of a boundary value problem to be solved for the temperature field within the solid continuum [16]
The finite element method provides the following equations for the numerical solution of equations (227-230)
nnnnnnn HFHt
C
1 (231)
e
jie
eij
e
dcNNCC (232)
ejiji
T
e
eij
ee
dNNdNKNHH (233)
eigi
e
ei
ee
dNdqNFF (234)
where and are the parameters that are different when using different methods like Crank-Nicolson Galerkin and so on The parameter is taken to be in the interval [01] C H and F are the element stiffness load and boundary matrices respectively N is the element shape functions gq is the heat flow K is the thermal conductivity tensor
21
The boundary conditions for temperature flux convection and radiation are
)(
)(
)(
42
4112 TTF
n
T
TThn
T
qn
Tk
tzyxfT
w
sz
(235)
where T is the temperature k is the thermal conductivity n is the normal direction of the boundary szq
is the heat flux vector h is the convective
heat transfer coefficient wT is the surface temperature of the solid T is
the fluid temperature is the emissivity is the Stefan Boltzmann constant
223 FEM model for mechanical field
The equations that govern analyses of the behavior of a solid continuum are those of momentum conservation ie the equations of motion For an analysis of small deformation of a solid continuum these are (in tensor form) [17]
iijij ub (236)
where ij is the Cauchy stress tensor ib the body force vector per unit
volume the density and iu the displacement vector
To establish a weak form from the strong one we multiply (236) by an arbitrary velocity ie the test function iv and integrate over the region
By introducing two boundary conditions ii uu on u and ijijn on
where 0v on u the above differential equation in the weak form
[17] is given as
22
dvdbvduvdv iiiiiiijji (237)
To perform the FE discretization of the weak form (237) means to divide the continuum volume into sub-elements where the displacement field in every element is approximated by shape functions )(xNI and nodal
displacements )(tuiI that is summation of their products [17]
)()()( xNtutxu IiIi (238)
By approximating the test functions with the same shape functions (Galerkin method) we obtain
0)(
)()(
)(
)(
)(
)(
int)(
int
int
ee
e
e
dNbdNff
NdNMM
x
NBdBff
fuMfv
TTexte
ext
Te
j
IjI
Te
extT
(239)
which must hold for an arbitrary v and which puts the FE equation in order
intffuM ext (240)
For a linear material C the FE equation that emerges is
23
)(
)(e
dCBBKKfKuuM TTeext (241)
224 Numerical procedure
For the induction hardening process three different analyses have been combined in one numerical procedure mechanical thermal-metallurgical and electromagnetic (EM) computations They are solved fully transiently Boundary conditions and material properties beside one unique geometric model were required by each of them
What is necessary to mention is that some characteristics of the material are interdependent The electric conductivity for instance depends on the temperature In addition all thermal properties depend on the temperature [18] The variation of the properties with the temperature makes the system to be non-linear
There is a high coupling grade between thermal and EM equations because the electrical and magnetic properties laws depend on temperature When the initial temperature is known the eddy current value is calculated and then used to compute the heat generated by the Joule effect [5] At each time step the convergence is checked Until a steady state between the heat and the temperature field is reached the temperature value will be recalculated for each magnetic sub-step
EM solver can be coupled with the thermal and mechanical solvers in order to take full advantage of their capabilities [7] Both the thermal and the EM solver run with implicit time integration For mechanical solver there are two time integration methods of explicit and implicit type
Explicit and implicit methods are numerical schemes for obtaining numerical solutions of time-dependent ordinary and partial differential equations as is required in computer simulations of physical processes Explicit methods calculate the state of a system at a later time from the state of the system at the current time while implicit methods find a solution by solving an equation involving both the current state of the system and the later one [19] Here follows the difference between explicit and implicit methods
Implicit method
o More accurate
24
o It has large time step increment
o Convergence of each load step can be controlled to avoid error accumulation
o Iteration may not converge
Explicit method
o Less accurate
o It has small time step
o There is error accumulation and the error is difficult to estimate
o Iteration converges
However the implicit type has been governing the mechanical solver for the induction process in this thesis
Now let us go back to the couplings For the electromagnetic and structure interaction both the mechanical and the EM solver have distinct time steps By linear interpolation the EM fields are evaluated at the mechanical time step The two solvers will interact at each electromagnetic time step The EM solver will communicate the Lorentz force to the mechanical solver [7] resulting in an extra force in the mechanic equation
Lorentzext FfDt
Du (242)
where is total charge density is electrical conductivity extf is the
external force while LorentzF is the Lorentz force In turn the displacements
and deformations of the conductors are returned by the mechanical solver
When it comes to the thermal coupling at each electromagnetic time step the EM solver will communicate the extra Joule heating power term and the thermal solver will communicate the temperature
Figure 22 shows the interactions between the different solvers in LS-DYNA
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
19
dWWnjiS ji11)(
1))(
1(
(226)
where is the magnetic permeability n
is the normal vector is the volume and is the boundary surface of volume
Equation (220) and (221) form the FEM system with and a being the unknowns From this system only the outside stiffness matrix cannot be directly computed The calculation of this matrix will be made possible through the definition of the BEM system [7] The BEM system is used for the air and will not be shown in this report More information about it could be found in [7]
222 FEM model for temperature field
The steady state or transient temperature field on three dimensional geometries can also be solved by LS-DYNA Material properties may be temperature dependent and either isotopic or orthotropic A variety of time and temperature dependent boundary conditions can be specified including temperature flux convection and radiation The implementation of heat conduction into LS-DYNA is based on the work of Shapiro [16]
The differential equations of conduction of heat in a three-dimensional continuum is given by
Qkt
cijij
(227)
where )( txi is temperature )( ix is density )( ixcc is
the specific heat )( iijij xkk is thermal conductivity )( ixQQ is
internal heat generation rate per unit volume
The boundary conditions are
s on 1 (228)
20
ijij nk on 2 (229)
Initial conditions at 0t are given by
)(0 ix at 0tt (230)
where )(txx ii are coordinates as a function of time is prescribed
temperature on 1 and in is normal vector to 2
Equations (227-230) represent the strong form of a boundary value problem to be solved for the temperature field within the solid continuum [16]
The finite element method provides the following equations for the numerical solution of equations (227-230)
nnnnnnn HFHt
C
1 (231)
e
jie
eij
e
dcNNCC (232)
ejiji
T
e
eij
ee
dNNdNKNHH (233)
eigi
e
ei
ee
dNdqNFF (234)
where and are the parameters that are different when using different methods like Crank-Nicolson Galerkin and so on The parameter is taken to be in the interval [01] C H and F are the element stiffness load and boundary matrices respectively N is the element shape functions gq is the heat flow K is the thermal conductivity tensor
21
The boundary conditions for temperature flux convection and radiation are
)(
)(
)(
42
4112 TTF
n
T
TThn
T
qn
Tk
tzyxfT
w
sz
(235)
where T is the temperature k is the thermal conductivity n is the normal direction of the boundary szq
is the heat flux vector h is the convective
heat transfer coefficient wT is the surface temperature of the solid T is
the fluid temperature is the emissivity is the Stefan Boltzmann constant
223 FEM model for mechanical field
The equations that govern analyses of the behavior of a solid continuum are those of momentum conservation ie the equations of motion For an analysis of small deformation of a solid continuum these are (in tensor form) [17]
iijij ub (236)
where ij is the Cauchy stress tensor ib the body force vector per unit
volume the density and iu the displacement vector
To establish a weak form from the strong one we multiply (236) by an arbitrary velocity ie the test function iv and integrate over the region
By introducing two boundary conditions ii uu on u and ijijn on
where 0v on u the above differential equation in the weak form
[17] is given as
22
dvdbvduvdv iiiiiiijji (237)
To perform the FE discretization of the weak form (237) means to divide the continuum volume into sub-elements where the displacement field in every element is approximated by shape functions )(xNI and nodal
displacements )(tuiI that is summation of their products [17]
)()()( xNtutxu IiIi (238)
By approximating the test functions with the same shape functions (Galerkin method) we obtain
0)(
)()(
)(
)(
)(
)(
int)(
int
int
ee
e
e
dNbdNff
NdNMM
x
NBdBff
fuMfv
TTexte
ext
Te
j
IjI
Te
extT
(239)
which must hold for an arbitrary v and which puts the FE equation in order
intffuM ext (240)
For a linear material C the FE equation that emerges is
23
)(
)(e
dCBBKKfKuuM TTeext (241)
224 Numerical procedure
For the induction hardening process three different analyses have been combined in one numerical procedure mechanical thermal-metallurgical and electromagnetic (EM) computations They are solved fully transiently Boundary conditions and material properties beside one unique geometric model were required by each of them
What is necessary to mention is that some characteristics of the material are interdependent The electric conductivity for instance depends on the temperature In addition all thermal properties depend on the temperature [18] The variation of the properties with the temperature makes the system to be non-linear
There is a high coupling grade between thermal and EM equations because the electrical and magnetic properties laws depend on temperature When the initial temperature is known the eddy current value is calculated and then used to compute the heat generated by the Joule effect [5] At each time step the convergence is checked Until a steady state between the heat and the temperature field is reached the temperature value will be recalculated for each magnetic sub-step
EM solver can be coupled with the thermal and mechanical solvers in order to take full advantage of their capabilities [7] Both the thermal and the EM solver run with implicit time integration For mechanical solver there are two time integration methods of explicit and implicit type
Explicit and implicit methods are numerical schemes for obtaining numerical solutions of time-dependent ordinary and partial differential equations as is required in computer simulations of physical processes Explicit methods calculate the state of a system at a later time from the state of the system at the current time while implicit methods find a solution by solving an equation involving both the current state of the system and the later one [19] Here follows the difference between explicit and implicit methods
Implicit method
o More accurate
24
o It has large time step increment
o Convergence of each load step can be controlled to avoid error accumulation
o Iteration may not converge
Explicit method
o Less accurate
o It has small time step
o There is error accumulation and the error is difficult to estimate
o Iteration converges
However the implicit type has been governing the mechanical solver for the induction process in this thesis
Now let us go back to the couplings For the electromagnetic and structure interaction both the mechanical and the EM solver have distinct time steps By linear interpolation the EM fields are evaluated at the mechanical time step The two solvers will interact at each electromagnetic time step The EM solver will communicate the Lorentz force to the mechanical solver [7] resulting in an extra force in the mechanic equation
Lorentzext FfDt
Du (242)
where is total charge density is electrical conductivity extf is the
external force while LorentzF is the Lorentz force In turn the displacements
and deformations of the conductors are returned by the mechanical solver
When it comes to the thermal coupling at each electromagnetic time step the EM solver will communicate the extra Joule heating power term and the thermal solver will communicate the temperature
Figure 22 shows the interactions between the different solvers in LS-DYNA
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
20
ijij nk on 2 (229)
Initial conditions at 0t are given by
)(0 ix at 0tt (230)
where )(txx ii are coordinates as a function of time is prescribed
temperature on 1 and in is normal vector to 2
Equations (227-230) represent the strong form of a boundary value problem to be solved for the temperature field within the solid continuum [16]
The finite element method provides the following equations for the numerical solution of equations (227-230)
nnnnnnn HFHt
C
1 (231)
e
jie
eij
e
dcNNCC (232)
ejiji
T
e
eij
ee
dNNdNKNHH (233)
eigi
e
ei
ee
dNdqNFF (234)
where and are the parameters that are different when using different methods like Crank-Nicolson Galerkin and so on The parameter is taken to be in the interval [01] C H and F are the element stiffness load and boundary matrices respectively N is the element shape functions gq is the heat flow K is the thermal conductivity tensor
21
The boundary conditions for temperature flux convection and radiation are
)(
)(
)(
42
4112 TTF
n
T
TThn
T
qn
Tk
tzyxfT
w
sz
(235)
where T is the temperature k is the thermal conductivity n is the normal direction of the boundary szq
is the heat flux vector h is the convective
heat transfer coefficient wT is the surface temperature of the solid T is
the fluid temperature is the emissivity is the Stefan Boltzmann constant
223 FEM model for mechanical field
The equations that govern analyses of the behavior of a solid continuum are those of momentum conservation ie the equations of motion For an analysis of small deformation of a solid continuum these are (in tensor form) [17]
iijij ub (236)
where ij is the Cauchy stress tensor ib the body force vector per unit
volume the density and iu the displacement vector
To establish a weak form from the strong one we multiply (236) by an arbitrary velocity ie the test function iv and integrate over the region
By introducing two boundary conditions ii uu on u and ijijn on
where 0v on u the above differential equation in the weak form
[17] is given as
22
dvdbvduvdv iiiiiiijji (237)
To perform the FE discretization of the weak form (237) means to divide the continuum volume into sub-elements where the displacement field in every element is approximated by shape functions )(xNI and nodal
displacements )(tuiI that is summation of their products [17]
)()()( xNtutxu IiIi (238)
By approximating the test functions with the same shape functions (Galerkin method) we obtain
0)(
)()(
)(
)(
)(
)(
int)(
int
int
ee
e
e
dNbdNff
NdNMM
x
NBdBff
fuMfv
TTexte
ext
Te
j
IjI
Te
extT
(239)
which must hold for an arbitrary v and which puts the FE equation in order
intffuM ext (240)
For a linear material C the FE equation that emerges is
23
)(
)(e
dCBBKKfKuuM TTeext (241)
224 Numerical procedure
For the induction hardening process three different analyses have been combined in one numerical procedure mechanical thermal-metallurgical and electromagnetic (EM) computations They are solved fully transiently Boundary conditions and material properties beside one unique geometric model were required by each of them
What is necessary to mention is that some characteristics of the material are interdependent The electric conductivity for instance depends on the temperature In addition all thermal properties depend on the temperature [18] The variation of the properties with the temperature makes the system to be non-linear
There is a high coupling grade between thermal and EM equations because the electrical and magnetic properties laws depend on temperature When the initial temperature is known the eddy current value is calculated and then used to compute the heat generated by the Joule effect [5] At each time step the convergence is checked Until a steady state between the heat and the temperature field is reached the temperature value will be recalculated for each magnetic sub-step
EM solver can be coupled with the thermal and mechanical solvers in order to take full advantage of their capabilities [7] Both the thermal and the EM solver run with implicit time integration For mechanical solver there are two time integration methods of explicit and implicit type
Explicit and implicit methods are numerical schemes for obtaining numerical solutions of time-dependent ordinary and partial differential equations as is required in computer simulations of physical processes Explicit methods calculate the state of a system at a later time from the state of the system at the current time while implicit methods find a solution by solving an equation involving both the current state of the system and the later one [19] Here follows the difference between explicit and implicit methods
Implicit method
o More accurate
24
o It has large time step increment
o Convergence of each load step can be controlled to avoid error accumulation
o Iteration may not converge
Explicit method
o Less accurate
o It has small time step
o There is error accumulation and the error is difficult to estimate
o Iteration converges
However the implicit type has been governing the mechanical solver for the induction process in this thesis
Now let us go back to the couplings For the electromagnetic and structure interaction both the mechanical and the EM solver have distinct time steps By linear interpolation the EM fields are evaluated at the mechanical time step The two solvers will interact at each electromagnetic time step The EM solver will communicate the Lorentz force to the mechanical solver [7] resulting in an extra force in the mechanic equation
Lorentzext FfDt
Du (242)
where is total charge density is electrical conductivity extf is the
external force while LorentzF is the Lorentz force In turn the displacements
and deformations of the conductors are returned by the mechanical solver
When it comes to the thermal coupling at each electromagnetic time step the EM solver will communicate the extra Joule heating power term and the thermal solver will communicate the temperature
Figure 22 shows the interactions between the different solvers in LS-DYNA
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
21
The boundary conditions for temperature flux convection and radiation are
)(
)(
)(
42
4112 TTF
n
T
TThn
T
qn
Tk
tzyxfT
w
sz
(235)
where T is the temperature k is the thermal conductivity n is the normal direction of the boundary szq
is the heat flux vector h is the convective
heat transfer coefficient wT is the surface temperature of the solid T is
the fluid temperature is the emissivity is the Stefan Boltzmann constant
223 FEM model for mechanical field
The equations that govern analyses of the behavior of a solid continuum are those of momentum conservation ie the equations of motion For an analysis of small deformation of a solid continuum these are (in tensor form) [17]
iijij ub (236)
where ij is the Cauchy stress tensor ib the body force vector per unit
volume the density and iu the displacement vector
To establish a weak form from the strong one we multiply (236) by an arbitrary velocity ie the test function iv and integrate over the region
By introducing two boundary conditions ii uu on u and ijijn on
where 0v on u the above differential equation in the weak form
[17] is given as
22
dvdbvduvdv iiiiiiijji (237)
To perform the FE discretization of the weak form (237) means to divide the continuum volume into sub-elements where the displacement field in every element is approximated by shape functions )(xNI and nodal
displacements )(tuiI that is summation of their products [17]
)()()( xNtutxu IiIi (238)
By approximating the test functions with the same shape functions (Galerkin method) we obtain
0)(
)()(
)(
)(
)(
)(
int)(
int
int
ee
e
e
dNbdNff
NdNMM
x
NBdBff
fuMfv
TTexte
ext
Te
j
IjI
Te
extT
(239)
which must hold for an arbitrary v and which puts the FE equation in order
intffuM ext (240)
For a linear material C the FE equation that emerges is
23
)(
)(e
dCBBKKfKuuM TTeext (241)
224 Numerical procedure
For the induction hardening process three different analyses have been combined in one numerical procedure mechanical thermal-metallurgical and electromagnetic (EM) computations They are solved fully transiently Boundary conditions and material properties beside one unique geometric model were required by each of them
What is necessary to mention is that some characteristics of the material are interdependent The electric conductivity for instance depends on the temperature In addition all thermal properties depend on the temperature [18] The variation of the properties with the temperature makes the system to be non-linear
There is a high coupling grade between thermal and EM equations because the electrical and magnetic properties laws depend on temperature When the initial temperature is known the eddy current value is calculated and then used to compute the heat generated by the Joule effect [5] At each time step the convergence is checked Until a steady state between the heat and the temperature field is reached the temperature value will be recalculated for each magnetic sub-step
EM solver can be coupled with the thermal and mechanical solvers in order to take full advantage of their capabilities [7] Both the thermal and the EM solver run with implicit time integration For mechanical solver there are two time integration methods of explicit and implicit type
Explicit and implicit methods are numerical schemes for obtaining numerical solutions of time-dependent ordinary and partial differential equations as is required in computer simulations of physical processes Explicit methods calculate the state of a system at a later time from the state of the system at the current time while implicit methods find a solution by solving an equation involving both the current state of the system and the later one [19] Here follows the difference between explicit and implicit methods
Implicit method
o More accurate
24
o It has large time step increment
o Convergence of each load step can be controlled to avoid error accumulation
o Iteration may not converge
Explicit method
o Less accurate
o It has small time step
o There is error accumulation and the error is difficult to estimate
o Iteration converges
However the implicit type has been governing the mechanical solver for the induction process in this thesis
Now let us go back to the couplings For the electromagnetic and structure interaction both the mechanical and the EM solver have distinct time steps By linear interpolation the EM fields are evaluated at the mechanical time step The two solvers will interact at each electromagnetic time step The EM solver will communicate the Lorentz force to the mechanical solver [7] resulting in an extra force in the mechanic equation
Lorentzext FfDt
Du (242)
where is total charge density is electrical conductivity extf is the
external force while LorentzF is the Lorentz force In turn the displacements
and deformations of the conductors are returned by the mechanical solver
When it comes to the thermal coupling at each electromagnetic time step the EM solver will communicate the extra Joule heating power term and the thermal solver will communicate the temperature
Figure 22 shows the interactions between the different solvers in LS-DYNA
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
22
dvdbvduvdv iiiiiiijji (237)
To perform the FE discretization of the weak form (237) means to divide the continuum volume into sub-elements where the displacement field in every element is approximated by shape functions )(xNI and nodal
displacements )(tuiI that is summation of their products [17]
)()()( xNtutxu IiIi (238)
By approximating the test functions with the same shape functions (Galerkin method) we obtain
0)(
)()(
)(
)(
)(
)(
int)(
int
int
ee
e
e
dNbdNff
NdNMM
x
NBdBff
fuMfv
TTexte
ext
Te
j
IjI
Te
extT
(239)
which must hold for an arbitrary v and which puts the FE equation in order
intffuM ext (240)
For a linear material C the FE equation that emerges is
23
)(
)(e
dCBBKKfKuuM TTeext (241)
224 Numerical procedure
For the induction hardening process three different analyses have been combined in one numerical procedure mechanical thermal-metallurgical and electromagnetic (EM) computations They are solved fully transiently Boundary conditions and material properties beside one unique geometric model were required by each of them
What is necessary to mention is that some characteristics of the material are interdependent The electric conductivity for instance depends on the temperature In addition all thermal properties depend on the temperature [18] The variation of the properties with the temperature makes the system to be non-linear
There is a high coupling grade between thermal and EM equations because the electrical and magnetic properties laws depend on temperature When the initial temperature is known the eddy current value is calculated and then used to compute the heat generated by the Joule effect [5] At each time step the convergence is checked Until a steady state between the heat and the temperature field is reached the temperature value will be recalculated for each magnetic sub-step
EM solver can be coupled with the thermal and mechanical solvers in order to take full advantage of their capabilities [7] Both the thermal and the EM solver run with implicit time integration For mechanical solver there are two time integration methods of explicit and implicit type
Explicit and implicit methods are numerical schemes for obtaining numerical solutions of time-dependent ordinary and partial differential equations as is required in computer simulations of physical processes Explicit methods calculate the state of a system at a later time from the state of the system at the current time while implicit methods find a solution by solving an equation involving both the current state of the system and the later one [19] Here follows the difference between explicit and implicit methods
Implicit method
o More accurate
24
o It has large time step increment
o Convergence of each load step can be controlled to avoid error accumulation
o Iteration may not converge
Explicit method
o Less accurate
o It has small time step
o There is error accumulation and the error is difficult to estimate
o Iteration converges
However the implicit type has been governing the mechanical solver for the induction process in this thesis
Now let us go back to the couplings For the electromagnetic and structure interaction both the mechanical and the EM solver have distinct time steps By linear interpolation the EM fields are evaluated at the mechanical time step The two solvers will interact at each electromagnetic time step The EM solver will communicate the Lorentz force to the mechanical solver [7] resulting in an extra force in the mechanic equation
Lorentzext FfDt
Du (242)
where is total charge density is electrical conductivity extf is the
external force while LorentzF is the Lorentz force In turn the displacements
and deformations of the conductors are returned by the mechanical solver
When it comes to the thermal coupling at each electromagnetic time step the EM solver will communicate the extra Joule heating power term and the thermal solver will communicate the temperature
Figure 22 shows the interactions between the different solvers in LS-DYNA
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
23
)(
)(e
dCBBKKfKuuM TTeext (241)
224 Numerical procedure
For the induction hardening process three different analyses have been combined in one numerical procedure mechanical thermal-metallurgical and electromagnetic (EM) computations They are solved fully transiently Boundary conditions and material properties beside one unique geometric model were required by each of them
What is necessary to mention is that some characteristics of the material are interdependent The electric conductivity for instance depends on the temperature In addition all thermal properties depend on the temperature [18] The variation of the properties with the temperature makes the system to be non-linear
There is a high coupling grade between thermal and EM equations because the electrical and magnetic properties laws depend on temperature When the initial temperature is known the eddy current value is calculated and then used to compute the heat generated by the Joule effect [5] At each time step the convergence is checked Until a steady state between the heat and the temperature field is reached the temperature value will be recalculated for each magnetic sub-step
EM solver can be coupled with the thermal and mechanical solvers in order to take full advantage of their capabilities [7] Both the thermal and the EM solver run with implicit time integration For mechanical solver there are two time integration methods of explicit and implicit type
Explicit and implicit methods are numerical schemes for obtaining numerical solutions of time-dependent ordinary and partial differential equations as is required in computer simulations of physical processes Explicit methods calculate the state of a system at a later time from the state of the system at the current time while implicit methods find a solution by solving an equation involving both the current state of the system and the later one [19] Here follows the difference between explicit and implicit methods
Implicit method
o More accurate
24
o It has large time step increment
o Convergence of each load step can be controlled to avoid error accumulation
o Iteration may not converge
Explicit method
o Less accurate
o It has small time step
o There is error accumulation and the error is difficult to estimate
o Iteration converges
However the implicit type has been governing the mechanical solver for the induction process in this thesis
Now let us go back to the couplings For the electromagnetic and structure interaction both the mechanical and the EM solver have distinct time steps By linear interpolation the EM fields are evaluated at the mechanical time step The two solvers will interact at each electromagnetic time step The EM solver will communicate the Lorentz force to the mechanical solver [7] resulting in an extra force in the mechanic equation
Lorentzext FfDt
Du (242)
where is total charge density is electrical conductivity extf is the
external force while LorentzF is the Lorentz force In turn the displacements
and deformations of the conductors are returned by the mechanical solver
When it comes to the thermal coupling at each electromagnetic time step the EM solver will communicate the extra Joule heating power term and the thermal solver will communicate the temperature
Figure 22 shows the interactions between the different solvers in LS-DYNA
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
24
o It has large time step increment
o Convergence of each load step can be controlled to avoid error accumulation
o Iteration may not converge
Explicit method
o Less accurate
o It has small time step
o There is error accumulation and the error is difficult to estimate
o Iteration converges
However the implicit type has been governing the mechanical solver for the induction process in this thesis
Now let us go back to the couplings For the electromagnetic and structure interaction both the mechanical and the EM solver have distinct time steps By linear interpolation the EM fields are evaluated at the mechanical time step The two solvers will interact at each electromagnetic time step The EM solver will communicate the Lorentz force to the mechanical solver [7] resulting in an extra force in the mechanic equation
Lorentzext FfDt
Du (242)
where is total charge density is electrical conductivity extf is the
external force while LorentzF is the Lorentz force In turn the displacements
and deformations of the conductors are returned by the mechanical solver
When it comes to the thermal coupling at each electromagnetic time step the EM solver will communicate the extra Joule heating power term and the thermal solver will communicate the temperature
Figure 22 shows the interactions between the different solvers in LS-DYNA
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
25
Figure 22 Interactions between the different solvers
For the induction heating analyses the solver works the following way it assumes a current which oscillates very rapidly compared to the total time of the process The solver works in the time domain and not in the frequency domain in order to easily take into account coilworkpiece motion as well as the time evolution of the EM parameters An EM time step must be compatible with the frequency (such that there are at least a few dozens of steps in the period of the current) In practice this means that a full eddy-current problem is solved on a quarter-period with a micro EM time step see Figure 23 The number of these micro steps in a quarter period can be specified by a software user
An average of the EM fields during this half-period and the joule heating are computed Then it is assumed that the properties of the material do not change for the next periods of the current These properties depend mostly on the temperature therefore the assumption can be considered accurate as long as the temperature does not change too much No EM computation is done during these periods only the averaged joule heating power is given to the thermal solver But as the temperature changes and thus the electrical conductivity the EM fields need to be updated accordingly so another full eddy current resolution is computed for a half-period of the current giving new averaged EM fields and an update of the Joule heating power [7]
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
26
Figure 23 Inductive heating time stepping
On the other hand the latent heat of phase transformations couples the thermal and metallurgical parts In the heating process phase transformation will happen (for this particular material ndash C45) from ferrite and pearlite to austenite at austenitization temperature while in the cooling process phase transformation will happen from austenite to martensite provided that the cooling rate is enough high
23 Microstructures in numerical model
There are five microstructures considered in the numerical model bainite ferrite pearlite martensite and austenite In LS-DYNA the phase transformation during heating is calculated by re-austenitization model according to Oddy et al [20] The grain growth will be activated when the temperature exceeds a threshold value T
)ln( baGRCCGRCMA
BT
(243)
where A B a b are the grain growth parameters GRCM is the grain growth parameter with respect to the concentration of metals in the workpiece (B+Co+Mo+Cr+Ni+Mn+Si+V+W+Cu+Al+As+Ti) and GRCC
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
27
is the grain growth parameter with respect to the concentration of non-metals in the workpiece (C+P)
When the temperature exceeds the threshold value the rate equation for the grain growth is
RT
Q
eg
kg
2 (244)
In this equation Q is the grain growth activation energy divided by the universal gas constant R while k is the growth parameter
When the grain growth is activated the rate equation for the re-austenitization is given as
))(
())(ln(1
T
xx
xx
xnx aeun
n
aeu
eua
(245)
where
2)()( 1c
sTTcT (246)
n is the grain growth parameter for the austenite formation c1 and c2 are the empirical grain growth parameters sT is the start temperature eux is the
eutectoid fraction and ax is the result of a normalized eutectoid austenite
fraction multiplied by the eutectoid fraction
The phase distributions during cooling (Li et al [21]) are calculated by solving the following rate equation for phase transitions (k = 2 for ferrite k = 3 for pearlite and k = 4 for bainite)
432)()( kXfQTCGgX kkkkkk (247)
where
432)1()( 40)1(40 kXXKf kk X
k
X
kkk (248)
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
28
and
eqkk xxX (249)
In the Equations (247) (248) and (249) G is the grain size number C is the chemical composition kT is the temperature kQ is the activation
energy kX is the actual phase and kx is the true amount of phase
The true amount of martensite (k = 5) is modeled by using the true amount of the austenite left after the bainite phase
)1( )(
15
TMSexx (250)
where x1 is the true amount of austenite left for the reaction α is a material dependent constant and MS is the start temperature of the martensitic reaction
The start temperatures are calculated with respect to the chemical composition
Ferrite
TiAsAlPCuCrMn
WMoVSiNiCKFS
400120400700201130
1135311047442152031185)(
(251)
Pearlite
WAsCrSiNiMnKPS 4629091629916710996)( (252)
Bainite
MoCrNiMnCKBS 4134153558910)( (253)
Martensite
SiCoMoCrNiMnCKMS 571057112717430423812)( (254)
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
29
The below figure is used to define the activation energy divided by the universal gas constant for the diffusion reaction of the austenite-ferrite reaction the austenite-pearlite reaction and the austenite-bainite reaction
Figure 24 CCT diagram for C45 material [5]
24 Numerical determination of hardness
Hardness can be predicted in the heat-altered zone with the knowledge of the thermal and metallurgical history The rule of mixtures is used to calculated the hardness which is
PFPFBBMM HvXXHvXHvXHv )( (255)
where Hv is the hardness in Vickers MX BX FX and PX are the volume fraction of martensite bainite ferrite and pearlite respectively and MHv BHv and PFHv are the hardness of martensite bainite and the mixture of ferrite and pearlite respectively Empirically based formulas developed by Maynier et al [22] were used in the study for the calculation of those hardnesses as functions of steel composition and cooling rate
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
30
VrCrNiMnSiCHvM log211681127949127
(256)
VrMoCrNiMnSiC
MoCrNiMnSiCHvB
log)33201022555389(
19114465153330185323
(257)
VrVCrNiSi
MoCrNiMnSiCHv PF
log)130841910(
197612305322342
(258)
where Vr is the cooling rate at 700 in degrees Celsius per hour
One thing that needs to be mentioned is in order to obtain valid results ndash the element proportions must be located within the following chemical composition ranges 01 lt C lt 05 Si lt 1 Mn lt 2 Ni lt 4 Cr lt 3 Mo lt 1 V lt 02 Cu lt05 and 001 lt Al lt 005 [5]
An error with a standard deviation of about 20 Vickers is foreseen [2223] in Equations (256) and (257)
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
31
3 Simulation (FEM) model
In this chapter the modeling of induction heating and cooling of a cylindrical workpiece (a bar) is presented The bar is made of C45 steel with the radius of 10 mm and the length of 200 mm The inductor is made of copper with one turn the inner ring radius of 15 mm and the rectangular cross section of 10 x 15 mm The cooling tool has a constant temperature of 20˚C the shell radius of 15 mm and the length of 200 mm Both the inductor and cooling tool move together with the same speed rate of 20 mms
The LS_DYNA FEM model of the inductor ring with a rectangular section the pipe standing for the cooling tool (sprouting water inside) and the bar is shown in 3-dimensional Figure 31
Figure 31 FEM model
31 Initial and boundary conditions
At the beginning the temperature of all parts is the same as the room temperature which is 20˚C
A contact (CONTACT_AUTOMATIC_SURFACE_TO_SURFACE) is used to model the thermal contact between the workpiece and the cooling tool defining the convection coefficient of 5500 Wm2K Radiation and convection parameters of the air-workpiece and air-coil are also considered
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
32
in the calculation (BOUNDARY_CONVECTION_SET and BOUNDARY_RADIATION_SET) see Table 31
Table 31 Radiation and convection parameters
Surface emissivity Stefan Boltzmann constant Wm2K4 Convection coefficient Wm2K
09 567E-08 5
The function that describes the voltage trend at the extremes of the inductor is represented by Eq (31)
)cos()()( 0 tttVtttVV (31)
where tt is the time on the thermal scale and t is the time on the electromagnetic scale (this diversification is necessary because of the coupling between the two different analyses is the pulsation and is the phase In particular f 2 where f is the frequency (being 27 KHz)
)(0 ttV is the amplitude of the voltage (being 31048 V)
In order to find the optimal time step simulations with different time steps have been done Below follows the figure showing chosen-element temperatures as the functions of time for four different time steps
Considering both the calculation time and the accuracy the conclusion was that the time step of 01 s was the optimal choice
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
33
Figure 32 Time step optimization
32 Meshing
The model is made in three dimensions as shown in Figure 33 Some modeling details are different from reality still not having significant influences on results solid cross section of the coil instead of the hollowed one and open coil instead of the closed one (only the open coil can indicate input and output segments of the current)
Figure 33 Assembled and reassembled FEM model
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
34
The inductor and the workpiece have been modeled with constant stress solid elements (type nr 1 in LS-DYNA) while the element type of the cooling tool is the shell of Belytschko-Tsay type (nr 2 in LS-DYNA) Meshing of the coil and cooling tool is simpler and the element size is bigger For the coil the solid element size is 2 x 15 x 14 mm in average and the total number of elements is 14371 For the cooling tool the element size is 235 x 667 mm and the total number of elements is 600 For the workpiece in order to save the calculation time considering the skin effect the solid element size is bigger at the middle axis than on the outside The critical outside element size (governing the time stepping) is 048 x 052 x 2 mm and the total number of elements on the whole bar is 567 566
33 Material properties
331 Thermal and electromagnetic properties of the bar
The high-quality structural steels with carbon content at least 045 are mostly used in induction heat treatment They are mainly used in the shafts such as crankshafts camshafts and so on C45 steel is the most widely used because the carbon content is normal and high hardness can be obtained C45 steel is also used in the example in this thesis Its chemical composition is shown below
Table 32 Nominal chemical composition of ISO C45 steel
C Si Mn S P Cr Mo Ni Al Cu Fe
045 025 065 0025 0008 04 01 04 001 017 Bal
In LS-DYNA currently it is not possible to include material property diversity of different phases to the material model called MAT_UHS (to utilize different thermal conductivities and specific heat for the different phases) So the curves of the thermal conductivity and specific heat shown in Figures 34 and 35 are used for all phases
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
35
Figure 34 Thermal conductivity for the C45 steel
Figure 35 Specific heat for the C45 steel
So far in LS-DYNA it is not possible to include any temperature dependence for permeability Therefore the average relative permeability is given by the following equation considering Figure 36
15293
851797615293
)151023(2)15823151023()31()1529315823(30
)(2)()()(
1
32312
x
xx
x
Tx
PTxTTPPTTP EESSr
(32)
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
36
where 1T (being 29315 K) is the initial temperature of the workpiece 2T (being 82315 K) is the temperature when relative permeability starts changing 3T (being 102315 K) is the temperature when relative
permeability stops changing SP (being 30) is the relative permeability
corresponding to 1T EP (being 1) is the relative permeability
corresponding to 3T and x is the assumed peak temperature
Figure 36 Relative permeability as function of temperature
The procedure is to assume different peak temperature calculate the relative permeability in the air and then re-calculate the temperature aiming in minimizing the difference between the assumed and re-calculated peak temperature So this procedure gives the relative permeability in air of 15854
The electric conductivity of C45 steel is given as a function of temperature below
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
37
Figure 37 Electric conductivity of C45 steel
332 Mechanical and metallurgical properties of the bar
The Poissons ratio and the Youngs modulus are constant 03 and 2050e+5 MPa respectively An average value of 7600 kgmsup3 is used for the density When it comes to yield stress ndash effective plastic strain properties there are five figures for different plastic hardening curves (austenite ferrite pearlite bainite and martensite respectively)
Figure 38 Yield stress vs effective plastic strain for different phases
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
38
The start temperature for ferritic pearlitic bainitic and martensitic transformations are 1039 K 996 K 837 K and 587 K respectively And the temperature for instantaneous transformation of ferrite to austenite is 1185 K The initial phase proportion is 40 pearlite and 60 ferrite
The latent heat for the transformation of ferrite pearlite and bainite into austenite is 59536 Jm3 And the latent heat for the decomposition of austenite into martensite is 66151 Jm3
333 Material properties of the inductor
In order to simplify the model the parameters of copper have been considered temperature independent [5]
Table 33 Material parameters of the inductor
Specific heat
[J(kg K)]
Thermal conductivity [W(m K)]
Density [kgmsup3]
Electric conductivity
[Sm]
Poissons ratio
Youngs modulus [MPa]
Permeability [Hm]
Inductor 386 400 8930 59E7 03 2050E5 1257E-7
34 Limitations
Some limitations have to be considered in the analysis Here is the list
The density can only be described by a constant value The impact of this will be that the accuracy will decrease if density changes with the temperature
2D axisymmetrical FEM modeling is still not available in LS-DYNA The impact of this is that the 3D-simulations take longer time
The thermal conductivity and specific heat cannot be set for different phases The impact of this is that the accuracy will decrease
The permeability can only be described as a constant ndash leading to a decreased accuracy
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
39
The CFL (Courant Friedrich Levy 1928) condition is an important convergence condition when solving partial differential equations such as the equations in the eddy current solver In this case it is based on the magnetic diffusion time step size of the element The method that LSTC (LS-DYNA developer) is currently using to solve the coupled FEM-BEM system has been to actually decouple these 2 systems and solve them in an iterative way This often necessitates very small time steps smaller than the CFL LSTC is currently working on a new method to actually solve the coupled system using GMRES methodology which seems to allow significantly larger time steps GMRES is the Generalized Minimal RESidual method ie an iterative method for the numerical solution of a non-symmetric system of linear equations However this method is not yet available in LS-DYNA
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
40
4 Analysis and discussion of the simulation results
In order to make simulations happen within reasonable time frame the bar length has been cut to contain only three cross section of it with a length of 6 mm as shown in Figure 41 The simulation results have been obtained with MAT_UHS_STEEL material model Within that model users have possibility to switch the HEAT parameter to activate the heatingcooling mechanism
=0 ndash Heating is not activated No transformation to austenite is possible
=1 ndash Heating is activated Transformation to austenite is possible
=2 ndash Automatic switching between heating and cooling LS-DYNA checks the temperature gradient and calls the appropriate algorithm
lt0 ndash Switch between heating (equal to 1) and cooling (equal to 0) is defined by a time dependent load curve
Figure 41 New bar - three cross section of the whole bar
Automatic switching between heating and cooling HEAT = 2 has been used in the analysis
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
41
41 Magnetic results
Figures 42 and 43 show the magnetic field distribution on the bar cross section at three different times and the relative position in the production process respectively
Figure 42 The magnetic field distribution of the bar at different times
Figure 43 Position of the coil and workpiece at different times
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
42
At the time equal to 0 s the inductor starts moving towards the bar First at the time equal to 15 s the notable values of the magnetic field can be obtained in the first two element rows At the time equal to 31 s the value of the magnetic field reaches the highest value in the process It can be noticed that at this time point the distance between the inductor and the bar is the smallest ndash the bar is inside the inductor The value of the magnetic field decreases with the inductor moving away from the bar
Numerical measurements of the magnetic field of four elements on the bar (Figure 44) are shown in Figure 45 From the core to the surface the four elements are A B C and D respectively From the graph it can be seen that the more distant elements are from the core the higher value of the magnetic field can be obtained
Figure 44 The position of the elements ndash A B C and D from the left to the right
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
43
Figure 45 Magnetic field as a function of time for four elements
Here follows the figure showing the proximity effect ndash the inner side of the coil has been used to heat the workpiece Since the inductor is the coil the maximum current density is noticeable at the inner side of the coil
Figure 46 The contours of current density of the inductor
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
44
42 Thermal results
At the time 0 the inductor and the cooling tool start moving together towards the bar The temperature of the bar is equal to the environment temperature 29315 K At the process time of 3 s the heating process is going on the temperature of the bar is increasing and the bar is near the inductor At the process time of 4 s the bar starts entering the cooling tool Moreover the temperature of the bar reaches the peak value the temperature at the surface of the bar is higher than in the core
Further on the bar is exposed to the cooling process The heat losses are more obvious on the surface of the bar so the temperature will decrease faster the closer it is to the surface
Temperature measurements for the same four elements on the (Figure 44) have been done see Figure 47 The same observation as above can be concluded - the surface temperature reaches the peak value at the time of 4 s which is near 1400 K Then it starts decreasing very fast in the cooling process However the temperature of the core still increases until the process time is around 7 s
Figure 47 Temperatures as functions of time for the measured elements
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
45
43 Metallurgical results
At the end of the heating process the surface layer has been transformed to austenite ndash only four outside element rows have the austenite content at this moment The phase proportion of the elements at other position keeps the initial phase proportion
At the process time of 16 s when the cooling process is finished the situation is following All the austenite has been transferred into the martensite The inner ferrite and pearlite have not changed at all while no bainite appears from the beginning to the end of the process
This has been documented in the figures that follow The following figure shows the position of the six measured elements A to F
Figure 48 The position of the measured elements
The following figures show the five phase proportion contents through the time in different elements
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
46
Figure 49 Phase proportions in the element A as functions of time
The measured element A is at the surface of the bar In the beginning there is 60 ferrite and 40 pearlite then all of them transfer into austenite at about 3 s of the process time After 7th second austenite starts transferring into martensite So at the end of the cooling process 100 martensite can be obtained in the elements at the surface
Figure 410 shows the phase proportions in the measured element B (at the third row of the cross section) as functions of time As previously in the beginning there is 60 ferrite and 40 pearlite Then all of them transfer into austenite at the austenitization temperature (t = 35 s) At the time about 8 s the austenite starts transferring into the martensite After the end of cooling process 100 martensite can be obtained in the element Though the final phase proportion is the same as for the element A the transformation time is different
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
47
Figure 410 Phase proportions in the element B as functions of time
Figure 411 shows the phase proportions in the element C through the time (at the fourth element row) All pearlite and some ferrite have been transferred into austenite at about the process time of 4 s austenite starts transferring into the martensite after t = 8 s and until the end of the cooling process all austenite has been transferred The final phase proportions are about 50 ferrite and 50 martensite
Figure 411 Phase proportions in the element C as functions of time
Figure 412 shows the phase proportions in the element D (at the fifth element row) Only about 5 pearlite has been transferred into austenite soon after 4th second while ferrite amount have not changed At about the process time of 85 s austenite starts transferring into martensite After the end of the cooling process all austenite has been transferred into
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
48
martensite The final phase proportions are about 60 ferrite 35 pearlite and 5 martensite
Figure 412 Phase proportions in the element D as functions of time
Figure 413 shows phase proportions of the element E (at the sixth element row) From the graph it can be noticed that there are no phase transformations in this element
Figure 413 Phase proportions in the element E as functions of time
Considering the element F (at the core) we got the same result as the previous one ndash phase proportions are always 60 ferrite and 40 pearlite So from the sixth row to the core the phase proportions do not change through the whole process
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
49
Still some strange results can be obtained for a couple of elements Around 5th second the proportion of ferrite starts increasing after it has been reset to zero see Figure 414 This is something connected to a bug in the material model
Figure 414 Strange ferrite amount in some elements
The final micro-hardness in Vickers is shown in Figure 415 From the figure we notice the maximum value of the hardness at the surface of the bar 703 HV On the other side the core have not changed the initial hardness it is still 184 HV
Figure 415 Final micro-hardness in Vickers
Miscellaneous results of interest have been discussed in Appendix A
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse
50
5 Evaluation of the results
In the paper [5] Magnabosco et al use two samples to do the experimental tests One of them was subjected to the annealing heat treatment before the quenching process while the other one was left in its normalized state [5] After the cooling process the micro-hardness in Vickers in the radial direction of the specimen was measured to detect the penetration hardening Then those results were compared to the numerical ones (Sysweld)
The same has been done with the numerical result from this study but the comparison is made only to the normalized specimen We have to emphasize here that there is a large difference in the bar length in our and their [5] study The shorter bar that we used has been justified by the wish of reasonable running times
Figure 51 Comparison between the micro-hardness measurement in the experiment [5] and the values obtained with the numerical model
51
The numerical values of micro-hardness are in satisfactory agreement with experimental observations and a good prediction of the maximum value of micro-hardness was obtained
Magnabosco et al [5] made SEM analyses of the final phase proportions at different depths The specimen microstructures of normalized steel after induction hardening are shown in the Figure 52 Micrograph A shows the microstructures at 05 mm distance from the surface and we can notice that a complete martensitic micro-structure can be obtained Micrographs B and C (depths of 16 and 21 mm respectively) show that an increment of untransformed ferritic phase moves toward the specimen axis [5] In micrograph D (25 mm depth) the phase proportion has been kept the same in comparison with the initial situation
Figure 52 Specimen microstructures after induction hardening [5]
52
From the numerical model the final phase proportions are shown in the following pie charts (Figures 53 to 56) They show the microstructure proportions at 046 mm 1759 mm 2237 mm and 2706 mm distance from the surface respectively At 046 mm there is only martensite which is in line with the experimental results At 1759 mm all the pearlite and some of the ferrite have been transferred into martensite At 2237 mm some of the pearlite transferred into martensite but no ferrite While at 2706 mm the phase proportion does not change from the initial situation
Figure 53 Final phase proportion at 046 mm distance from the surface
Figure 54 Final phase proportion at 1759 mm distance from the surface
53
Figure 55 Final phase proportion at 2237 mm distance from the surface
Figure 56 Final phase proportion at 2706 mm distance from the surface
54
6 Conclusions
LS-DYNA FEM software has been used for simulations of an induction hardening process The aim was to develop a simulation model for induction heat treatment with coupling between the electro-magnetic thermal mechanical and metallurgical phenomenon The main study included also comparison of the results of the simulation with the literature values for evaluation and validation of the FEM software LS-DYNA as a tool for simulation of induction hardening
Because of the long computational times the numerical model of the bar has been made considerably smaller Apart from that the numerical results seem very reasonable
Three things are more essential than others when talking about the LS-DYNA capability to efficiently model this process
More stable material model (unrealistic ferritic occurrence at cooling see Figure 414)
Access to a 2D solver
Faster EM solver
LSTC is currently working on all these topics However during the time of writing the thesis these methods have not been available
55
Reference
[1] Yutaka Toi and Masakazu Takagaki (2008) Computational Modeling of Induction Hardening Process of Machine Parts WCECS San Francisco USA
[2] Torsten Holm Pelle Olsson and Eva Troell (2012) Steel and Its Heat Treatment Moumllndal Sweden
[3] JF Wu (2004) Numerical Simulation of Induction Heating Based on ANSYS J Manuf Sci Eng 32(l)58-62 Hangzhou China
[4] Daniel Williams (1995) Quench Systems for Induction Hardening Metal Heat Treating Cleveland Ohio USA
[5] I MagnaboscoP FerroA TizianiF Bonollo (2006) Induction heat treatment of a ISO C45 steel bar Experimental and numerical analysis Computational Materials Science 35 (2006) 98ndash106 Vicenza Italy
[6] Induction heating Available from lt httpenwikipediaorgwikiInduction_heating gt
[7] Pierre Lrsquo Eplattenier Inaki Caldichoury (2011) Electromagnetism and Linear Algebra in LSDYNA EM Theory manual LSTC-LS-DYNA-EM-THE11-1 Gramat France
[8] O Biro and K Preis (1989) On the use of the magnetic vector potential in the finite element analysis of three dimensional eddy currents IEEE Transaction on Magnetics 25 No 4 (1989) pp 3145ndash3159 USA
[9] Skin effect Available from lt httpenwikipediaorgwikiSkin_effectgt
[10] Proximity effect (electromagnetism) Available from lthttpenwikipediaorgwikiProximity_effect_(electromagnetism)gt
[11] Goumlran Broman (2003) Computational Engineering Karlskrona Sweden
[12] Ottosen N S and Petersson H (1992) Introduction to the Finite Element Method Prentice Hall Michigan USA
[13] G P Nikishkov (2004) Introduction to the Finite Element Method 2004 Lecture Notes University of Aizu Aizu-Wakamatsu 965-8580 Japan
[14] Boundary element method Available from lt httpenwikipediaorgwikiBoundary_element_methodgt
[15] R Rieben and D White (2006) Verification of high-order mixed finite element solution of transient magnetic diffusion problems IEEE Transaction on Magnetics 42 No1 (2006) pp 25ndash39 USA
[16] John OHallquist (1998) LS-DYNA Theoretical Manual Livermore Software Technology Corporation California USA
[17] Edin Omerspahic (2005) Modeling of Inelastic Effects in Metal Sheets and Identification of Material Parameters Chalmers University of Technology Goumlteborg Sweden
[18] Sven Wanser Laurent Wenbiihl Main Nicolas (1994) Computation of 3D Induction Hardening Problems by Combined Finite and Boundary Element Methods IEEE transactions on magnetics Vol30 No5 France
[19] Explicit and implicit methods Available from lthttpenwikipediaorgwikiExplicit_and_implicit_methodsgt
56
[20] ASOddy JMJ McDill and L Karlsson (1996) Microstructural predictions including arbitrary thermal histories reaustenitization and carbon segregation effects Can Metall Quart 1996 35(3) p 275-283 Ottawa Canada
[21] MV Li DV Niebuhr LL Meekisho and DG Atteridge (1998) A Computatinal model for te prediction of steel hardenability Metallurgical and materials transactions B 29B 661-672 Portland USA
[22] P Maynier J Dollet and P Bastien (1978) Hardenability Concepts with Applications to Steels DV Doane and JS Kirkaldy eds AIME New York NY pp 518-44 Chicago USA
[23] SYSTUS and SYSWELD 2000 manuals (2000) ESI GROUP Lyon French
[24] ASM Handbook (1998) Heat treating vol 4 1998
[25] J Yuan J Kang Y Rong and RD Sisson Jr (2003) FEM Modeling of Induction Hardening Processes in Steel JMEPEG (2003) 12589-596 Massachusetts USA
[26] Conjugate gradient method Available from lt httpenwikipediaorgwikiConjugate_gradient_methodgt
[27] Finite element method Available from lthttpenwikipediaorgwikiFinite_element_methodgt
[28] Equations of motion Available from lt httpenwikipediaorgwikiEquations_of_motiongt
[29] Klaus Weimar (2001) LS-DYNA Users Guide Rev 119 Hamburg Germany
[30] Heath Michael T (2002) Scientific computing an introductory survey 2nd ed Mc Graw Hill Illinois USA
[31] Ivan Oskarsson (2006) A new h-adaptive method for shell elements in LS-DYNA Lund University Lund Sweden
[32] Materials Algorithms Project Available from lthttpengm01msornlgovindexhtmlgt
[33] H Porzner (ESI Group) (2001) Private communication USA
57
Appendix A Miscellaneous results
The simulation results in the result relating chapters have been obtained with HEAT = 2 ndash Automatic switching between heating and cooling and run implicitly on the mechanical solver In order to check the LS-DYNArsquos capability to model the induction hardening process some other modeling techniques and features have been tested Here follows some results from the other methods and comparison with the results described in the previous chapter
Explicit mechanical solver
Figure A1 shows the ferrite distribution on the bar after the cooling process with the auto switching between heating and cooling and running explicitly on the mechanical solver It can be seen that the ferrite distribution at the surface is inhomogeneous If we check the ferrite amount in one element at the surface as shown in Figure A2 there is a strange phenomenon that some ferrite appears at very high cooling rate The reason for this error is probable bugs in the material model for the explicit software
Figure A1 The ferrite distribution of the bar after cooling
58
Figure A2 Ferrite phase transformations for the measured element
Implicit mechanical solver with curve switching between heating and cooling
As shown in Figure A3 this curve has been used as the HEAT parameter in MAT_UHS_STEEL material model to define the heating (=1) and cooling process (=0) for the bar
Figure A3 Curve used to switch between heating and cooling
Ferrite proportion was checked in the elements of the first and second row as shown in Figures A4 and A5
59
Figure A4 Amount of the ferrite as the functions of time in the measured elements ndash 1st row
Figure A5 Amount of the ferrite as the functions of time in the measured elements ndash 2nd row
60
While all the measured elements in the first row show the realistic result all checked elements in the second row have the unrealistic ferrite increase after 6th second (very high cooling rate) Other elements in the cross section do not show this strange behavior The reason is probably the mentioned bug
Implicit mechanical solver with 2 successive processes ndash heating and cooling enabled by INTERFACE_SPRINGBACK_LSDYNA
This attempt was about separating the whole process into two parts and running first the heating process (with an output which has been the input for the new process) and then the cooling process This has been made possible by using INTERFACE_SPRINGBACK_LSDYNA keyword where the number of history variable (NSHV) should be high enough to map all variables between the calculations
The result with the automatic switching is better than the one with 2 successive processes Figure A6 shows it clearly illustrating ferrite proportion in all the elements of the middle cross section We can see that the number of elements that have the unrealistic increase of ferrite is bigger than the one resulting from the automatic switching method
61
Figure A6 Comparison of the amount of ferrite in the measured elements between different methods
To sum up by comparing all the results the best ones have been achieved with the auto switching between heating and cooling running implicitly the mechanical solver
School of Engineering Department of Mechanical Engineering Blekinge Institute of Technology SE-371 79 Karlskrona SWEDEN
Telephone E-mail
+46 455-38 50 00 infobthse